Lactobacillus reuteri and use thereof

ABSTRACT

Provided is a strain CCFM8631 of  Lactobacillus reuteri  and use thereof. The strain CCFM8631 of  Lactobacillus reuteri  can significantly increase neurotransmitter 5-hydroxytryptamine level in peripheral blood, recover the hormone levels, for example testosterone and so on in peripheral blood of rat, normalize abnormal abundances of  Blautia  genus and  Turicibacter  genus,  Oscillospira  genus and  Bifidobacterium  genus in intestinal flora of rat affected by high-fat high-starch diet, show good tolerance to simulated gastrointestinal fluid and quickly colonize in intestinal, significantly improve pathological damages of tissues such as liver, duodenum and so on, and increase triglyceride and total cholesterol levels in serum and oral glucose tolerance of rat with metabolic syndrome caused by high-fat high-starch diet. The strain CCFM8631 of  Lactobacillus reuteri  can be used for preventing, relieving or treating metabolic disorder, such as metabolic syndrome, irritable bowel syndrome and mental diseases related to metabolic syndrome such as anxiety, depression and so on.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the priority of Chinese Patent Application No. 201710963119.2, filed on Oct. 17, 2017, and the disclosures of which are hereby incorporated by reference.

FIELD

The present disclosure relates to the field of microbe technology, specifically to a Lactobacillus reuteri and use thereof, especially to a Lactobacillus reuteri that is capable of modulating intestinal flora, modulating brain-gut axis and significantly alleviating metabolic syndrome, and use thereof.

BACKGROUND

Recent years, with the developing economy, life-styles of people in many countries have changed obviously. With the amount of physical activity has decreased, obesity rate has increased significantly, and prevalence rates of diabetes and metabolic syndrome have increased by a large margin. An epidemiology survey shows that 20% to 30% of the adults across the globe are suffering from metabolic syndrome. In 2013, a multicenter, multistage stratified, large-scale sampling survey carried out by Chinese Diabetes Society of Chinese Medical Association showed that among people over 20 years old in large and medium-sized cities, towns and countryside of China, prevalence rates of metabolic syndrome in men and women were 16.7% and 11.7%, respectively, and the total prevalence rate was 13.7%. Furthermore, the rate was continuously increasing. Analyses show that age, blood pressure, diabetes family history, obesity, hyperlipidemia, male, low income and little exercise are main related risk factors for metabolic syndrome. The survey also found that the rates of the overweight and the obesity among people have increased by a large margin, and prevalence rate of metabolic syndrome of male is significant higher than that of female at the same age among middle-aged crowd.

Metabolic syndrome is a clinical syndrome, which has simultaneous symptoms of central obesity, fasting blood glucose rising, high blood pressure, decrease of high-density lipoprotein cholesterol and increase of triacylglycerol, in which numerous hazardous factors basing on the abnormal pathological changes of carbohydrate metabolism, lipid metabolism and protein metabolism aggregates, and which promotes development of diabetes (type II) and cardiovascular diseases such as atherosclerosis and so on. Due to metabolic syndrome is a pathological condition in which numerous metabolic abnormalities aggregates, its occurrence is relates to insulin resistance, becoming a hot spot in the research field of cardiovascular diseases and diabetes, and raising many controversies at home and abroad. In addition, metabolic syndrome accompanies with disorder of intestinal microecosystem. Disorder of intestinal microecosystem may further lead to disorder of intestinal functions, nerve center functions and peripheral nerve functions, for example, intestinal inflammation, inflammatory bowel disease (IBD) and irritable bowel syndrome (IBS), abnormality of neurotransmitter 5-hydroxytryptamine level and level of some hormone and so on. Many researches have shown that abundances of intestinal microbes of some genus have intimate connection with intestinal diseases, for example, the abundance of Blautia genus will rise in intestinal flora of IBS patient, and the abundance of Oscillospira genus is closely related to the body mass index. At the same time, researches also show that mental diseases such as depression, anxiety and so on have intimate connection with metabolic syndrome, intestinal flora disorder, and low 5-hydroxytryptamine level in human body. Improving 5-hydroxytryptamine level in peripheral blood helps increasing neurotransmitter level of central nervous system, so that relieving symptoms of anxiety, depression and so on.

At present, all the drug treatments of metabolic syndrome aim to decrease all kinds of risk factors, and these drugs include: anti-obesity drugs for weight loss; dimethylbiguanide and thiazolidinediones for reducing insulin resistance; sulfonylurea and rosiglitazone for controlling blood glucose; fibrate and statin for improving disorder of lipid metabolism; captopril, amlodipine and so on for controlling the blood pressure; drugs for treating intestinal diseases such as IBD, IBS and so on, including glucocorticoid, immunosuppressant, psychotropic drugs and so on; drugs for mental diseases such as anxiety, depression and so on, including selective serotonin reuptake inhibitors such as paroxetine, noradrenaline, and specific 5-hydroxytryptamine antidepressant drugs such as mirtazapine and so on. All of the medicines above have certain therapeutic effects, but as the conditions getting worse, the amounts of medicine used increase, the interactions between the medicines as well as the toxic and side effects of medicines become significant, leading to adverse reaction of digestive tract and showing liver and renal toxicity in some degree. In consideration of problems of the medicines, early intervention in metabolic syndrome, intestinal disease and mental disease can effectively decrease onset risk of cardiovascular and cerebrovascular diseases, diabetes, inflammatory bowel diseases, depression and so on.

Probiotics are edible microbes that are beneficial to human health, which have potential functions of alleviating abnormal metabolism of blood glucose and blood lipid, and modulating intestinal flora proportion and brain-gut axis. Thus, there is important social and economy value to research and develop probiotic products that can effectively intervene the occurrence and development of metabolic syndrome, intestinal diseases and mental diseases.

At present, there is no patent about using probiotics to increase 5-hydroxytryptamine level so as to regulate brain-gut axis and relieve anxiety and depression. There is also no patent about modulating the abnormal abundance of Oscillospira genus to relieve metabolic diseases. Although there is related patent application (CN107083339A) that discloses adding Blautia bacteria to protect piglets from diarrhea, there is no patent about modulating the abnormal abundance of Blautia genus bacteria in intestinal tract so as to alleviate intestinal disease by the uptake of edible microbes (list of bacterium that can be permitted to be used in food, infant food, health products by National Health Commission of the People's Republic of China, 2014). In addition, there are some patents or patent application relating to compositions and preparation method thereof for preventing and curing metabolic syndrome. For example, CN104906263A discloses a composition consisting of tea polyphenol, procyanidin and POTENTILLAE DISCOLORIS HERBA extract, which is used to treat metabolic syndrome. CN105796674A discloses a traditional Chinese medicine composition comprising PLANTAGINIS SEMEN, COPTIDIS RHIZOMA and so on, which is capable of preventing and curing metabolic syndrome. In addition, a few patents relate to probiotics-containing compositions that are used to improve metabolic syndrome, and the methods for preparing the same. For example, CN105816623A discloses a probiotic-fermented traditional Chinese medicine composition being used to cure and improve metabolic syndrome, which is made from traditional Chinese medicine such as PANACIS QUINQUEFOLII RADIX, DIOSCOREAE RHIZOMA, MOUTAN CORTEX, PORIA by extracting and fermenting the extract with probiotics. All the above patents and patent applications are using traditional Chinese medicine components or a mixture of bacteria and traditional Chinese medicine to alleviate metabolic syndrome, in which the bacteria and the functions of the bacteria are not clear. CN105567586A discloses a Lactobacillus plantarum NCU116 with antidiabetic function, which achieves antidiabetic effects through modulating body blood glucose, blood lipid, hormone level and body metabolism. The Lactobacillus plantarum is screened and selected from bacteria in kimchi instead of human sources. No evidence shows that Lactobacillus plantarum can colonize in human intestinal tract and take effects. So far, there is no a human-sourced individual probiotic (such as Lactobacillus reuteri) that can colonize in human intestinal tract to relieve the metabolic syndrome, or to alleviate symptoms such as hyperglycemia, hyperlipidemia, intestinal flora imbalance, intestinal inflammation and so on, and related mental diseases.

SUMMARY

In view of above, an object of the present disclosure is to solve the problems in the prior art by providing a probiotics. The probiotics can colonize in intestinal tract of human body, improve 5-hydroxytryptamine level in peripheral blood, regulate brain-gut axis and recovering testosterone level in serum back to normal level, normalize abnormal abundances of Blautia genus, Turicibacter genus, Oscillospira genus and Bifidobacterium genus in intestinal flora, improve metabolic syndrome, relieve hyperglycemia, hyperlipidemia and inflammation of liver and duodenum, liver fibrosis and other symptoms.

The present disclosure provides a strain CCFM8631 of Lactobacillus reuteri, which is deposited at China General Microbiological Culture Collection Center (CGMCC, Address: Beijing Institute of Microbiology, Chinese Academy of Sciences, No. 1, Beichen West Road, Chaoyang District, Beijing, China) on Jul. 7, 2017, with an accession number CGMCC 14394.

In one embodiment, the present disclosure studies effect of strain CCFM8631 of Lactobacillus reuteri on intestinal flora imbalance caused by high-carbohydrate and high-fat diet. The results show that the uptake of strain CCFM8631 of Lactobacillus reuteri significantly recovers relative abundances of Bifidobacterium genus and Turicibacter genus in disordered intestinal microbes of rat feces, and also regulates the abundances of Oscillospira genus and Blautia genus in rat feces back to normal level. The intervention effect is obviously better than that of Lactobacillus rhamnosus LGG.

In one embodiment, the present disclosure studies protection effects of strain CCFM8631 of Lactobacillus reuteri on tissue damages of liver, duodenum and so on in rat with metabolic syndrome. The results show that administration of strain CCFM8631 of Lactobacillus reuteri by intragastric gavage significantly improves symptoms caused by high-fat high-starch diet, such as hepatocyte microvesicular steatosis, interstitial inflammatory cell infiltration, early fibrosis of liver tissue, duodenum villi broadening, interstitial edema, increasing of inflammatory cells and so on in rats, and the intervention effect is obviously better than that of Lactobacillus rhamnosus LGG.

In one embodiment, the present disclosure studies effect of strain CCFM8631 of Lactobacillus reuteri on (fasting) blood glucose level of rat with metabolic syndrome. The results show that administration of strain CCFM8631 of Lactobacillus reuteri by intragastric gavage obviously decreases the fasting blood glucose level of the model rat close to the blank control group. The ability of strain CCFM8631 of Lactobacillus reuteri on decreasing fasting blood glucose level of rat is better than that of rosiglitazone and Lactobacillus rhamnosus LGG by intragastric gavage administration.

In one embodiment, the present disclosure studies effect of strain CCFM8631 of Lactobacillus reuteri on oral glucose tolerance of rat with metabolic syndrome. The results show that strain CCFM8631 of Lactobacillus reuteri significantly improves oral glucose tolerance and the effect is better than that of Lactobacillus rhamnosus LGG, indicating that strain CCFM8631 of Lactobacillus reuteri can further decrease glucose level by improving glucose tolerance.

In one embodiment, the present disclosure studies effects of strain CCFM8631 of Lactobacillus reuteri on total cholesterol (TC) and triglyceride (TG) in serum of rat with metabolic syndrome, respectively. The results show that administration of strain CCFM8631 of Lactobacillus reuteri by intragastric gavage decreases levels of total cholesterol and triglyceride in serum.

Further, in one embodiment, the present disclosure studies effects of strain CCFM8631 of Lactobacillus reuteri on 5-HT and testosterone level in serum of rat with metabolic syndrome, respectively. The results show that administration of strain CCFM8631 of Lactobacillus reuteri by intragastric gavage improves 5-hydroxytryptamine (5-HT) level in rat serum, and reduces testosterone in serum back to normal level.

Therefore, the present disclosure provides use of strain CCFM8631 of Lactobacillus reuteri in preparing products that can improve metabolic syndrome, regulate intestinal flora or regulate brain-gut axis.

Therein, the improving metabolic syndrome is to relieve symptoms of hyperglycemia and hyperlipidemia, inflammation of liver and duodenum, and liver tissue fibrosis; the modulating intestinal flora is to normalize abnormal abundances of Blautia genus, Turicibacter genus, Oscillospira genus and Bifidobacterium genus in intestinal flora; and the modulating brain-gut axis as well as relieving anxiety and depression is to increase 5-hydroxytryptamine level in peripheral blood.

The product of the present disclosure includes but is not limited to health food or pharmaceutical preparation.

Therein, the health food includes but is not limited to microbial agent or fermented food.

Further, the present disclosure provides a microbial agent comprising the strain CCFM8631 of Lactobacillus reuteri.

Preferably, the viable count of the strain CCFM8631 of Lactobacillus reuteri in the microbial agent is more than 10⁶ CFU/g

The microbial agent of the present disclosure can be prepared by routine methods.

In some embodiments, the method for preparing the microbial agent is:

inoculating the strain CCFM8631 of Lactobacillus reuteri to a modified MRS medium at an inoculum size of 2 to 4 wt %, culturing for 18 to 20 h at 37° C. under anaerobic conditions, collecting bacteria, resuspending the bacteria with a protectant to reach a bacterial density of 10¹⁰ CFU/mL, culturing the suspension at 37° C. for 50 to 70 minutes under anaerobic conditions, and drying the resulting culture.

Therein, the modified MRS medium (MRS) in the present disclosure is prepared by the specific method as follows: dissolving 10 g of tryptone, 10 g of beef extract, 5 g of yeast powder, 20 g of glucose, 5 g of sodium acetate, 2 g of ammonium citrate dibasic, 2 g of dipotassium hydrogen phosphate, 0.5 g of magnesium sulfate heptahydrate, 1 mL of Tween-80, and 0.25 g of manganese sulfate monohydrate in water, diluting the mixture to 1000 mL with water, modulating the pH to 6.5, and autoclaving at 119-123° C. for 15 to 25 minutes.

The protectant in the method of the present disclosure is an aqueous solution that contains 100 g/L to 150 g/L of nonfat milk powder, 100 g/L to 150 g/L of maltodextrin and 140 g/L to 160 g/L of trehalose. That is, the protectant consists of nonfat milk powder, maltodextrin, trehalose and water, wherein the concentration of nonfat milk powder is from 100 g/L to 150 g/, the concentration of maltodextrin is from 100 g/L to 150 g/L, and the concentration of trehalose is from 140 g/L to 160 g/L.

Preferably, in the method of the present disclosure, bacteria collected after culturing in the modified MRS medium are subjected to washing with phosphate buffer solution for 2 to 4 times, and pH of the phosphate buffer solution is from 6.8 to 7.2.

The drying of the method in the present disclosure can be any of the drying procedures for bacteria solution, for example vacuum freeze-drying. In some embodiments, the drying of the present disclosure is vacuum freeze-drying after pre-freezing the bacteria at −15 to −20° C. for 8 to 14 h.

The present disclosure also provides a fermented food which is produced by using the strain CCFM8631 of Lactobacillus reuteri as a starter culture.

The fermented food is fermented dairy products, fermented bean products or fermented fruit and vegetable products.

The fermented dairy products include but are not limited to yogurt, sour cream and cheese. The fermented bean products include but are not limited to soymilk, fermented beans and bean paste. The fruits and vegetables in the fermented fruit and vegetable products include but are not limited to cucumber, carrot, beet, celery and cabbage.

The present disclosure also provides a pharmaceutical preparation, comprising an effective amount of the strain CCFM8631 of Lactobacillus reuteri and a pharmaceutically acceptable adjuvant.

The pharmaceutically acceptable adjuvant is one or more selected from the group consisting of filler, adhesive, wetting agent, disintegrating agent, lubricant, and flavoring agent.

In some embodiments of the present disclosure, the pharmaceutical preparation is a granule, a capsule, a tablet, a pill or an oral liquid.

The beneficial technical effects of the present disclosure are as follows.

The strain CCFM8631 of Lactobacillus reuteri of the present disclosure significantly increases neurotransmitter 5-hydroxytryptamine (5-HT) level in peripheral blood of rat, regulates brain-gut axis, relieves mental illnesses related to metabolic syndrome, for example anxiety, depression and so on, recovers the hormone level, for example testosterone and so on in peripheral blood of rat caused by high-fat high-starch diet, recovers abundances of Blautia genus, Turicibacter genus, Oscillospira genus and Bifidobacterium genus in abnormal intestinal flora of rat caused by high-fat high-starch diet. In addition, strain CCFM8631 of Lactobacillus reuteri has pretty good tolerance to simulated gastrointestinal fluid, and quickly colonizes in intestinal, significantly alleviates pathology damages of tissues, such as liver, duodenum and so on of rat with metabolic syndrome caused by high-fat high-starch diet; significantly improves oral glucose tolerance of rat with metabolic syndrome and decreases the under curve area of glucose tolerance test; significantly increases triglyceride and total cholesterol levels in serum of rat with metabolic syndrome caused by high-fat high-starch diet. The strain CCFM8631 of Lactobacillus reuteri of the present disclosure can be used to prepare health foods or medicines that improve metabolic syndrome, regulates intestinal flora, relieves irritable bowel syndrome, regulates brain-gut axis and alleviates mental illness such as anxiety, depression and so on, which has a pretty wide application prospect.

DESCRIPTION OF MICROBIOLOGICAL PRESERVATION

CCFM8631, classification name: Lactobacillus reuteri, is deposited at China General Microbiological Culture Collection Center (CGMCC, Address: Beijing Institute of Microbiology, Chinese Academy of Sciences, No. 1, Beichen West Road, Chaoyang District, Beijing, China) on Jul. 7, 2017, with an accession number CGMCC 14394.

BRIEF DESCRIPTION OF DRAWINGS

In order to describe the technical solutions in the examples of the present disclosure or the conventional art more clearly, the accompanying drawings used in description of the embodiments or the prior art will be illustrated briefly.

FIG. 1 shows colony morphology of strain CCFM8631 of Lactobacillus reuteri.

FIG. 2 shows effects of strain CCFM8631 of Lactobacillus reuteri on tissue structure of liver in rat with metabolic syndrome.

FIG. 3 shows effects of strain CCFM8631 of Lactobacillus reuteri on tissue structure of duodenum in rat with metabolic syndrome.

FIG. 4 shows effects of strain CCFM8631 of Lactobacillus reuteri on abundances of some intestinal microbes in rat with metabolic syndrome; and there are significant differences (P<0.05) between a, b and c groups.

FIG. 5 shows effects of strain CCFM8631 of Lactobacillus reuteri on oral glucose tolerance in rat with metabolic syndrome; and there are significant differences (P<0.05) between a, b and c groups.

FIG. 6 is a curve showing changes of blood glucose level in oral glucose tolerance test.

FIG. 7 shows the area under the curve (AUC_(glucose)) in oral glucose tolerance test.

FIG. 8 shows effects of strain CCFM8631 of Lactobacillus reuteri on total cholesterol (TC) in serum of rat with metabolic syndrome; and there are significant differences (P<0.05) between a, b and c groups.

FIG. 9 shows effects of strain CCFM8631 of Lactobacillus reuteri on triglyceride (TG) in serum of rat with metabolic syndrome; and there are significant differences (P<0.05) between a, b and c groups.

FIG. 10 shows effects of strain CCFM8631 of Lactobacillus reuteri on 5-hydroxytryptamine (5-HT) and testosterone levels of rat with metabolic syndrome; and there are significant differences (P<0.05) between a, b and c groups.

DETAILED DESCRIPTION

The present disclosure discloses a Lactobacillus reuteri and use thereof. One of ordinary skill in the art can learn from the contents herein and improve the process parameters appropriately. In particular, it shall be noted that all the similar substitutions and modifications are apparent to one of ordinary skill in the art and are to be considered within the scope of the present invention. The method and product of the present invention have been described with preferred examples. It is apparent that one of the ordinary skill in the art can make change or modify the combination to the method and product of the present invention without departing from the spirit, scope and spirit of the invention, therefore realizing and applying the techniques of the present invention. www

The strain CCFM8631 of Lactobacillus reuteri of the present disclosure has the following biology properties.

(1) Bacterium properties: Gram straining positive, slim rod-shape, no flagella, no spore

(2) Colony properties: convex colonies are formed after 36-hour culture, the edge is not smooth, the color is milky and non-transparent, the surface is moist and smooth, and no pigment is produce. See FIG. 1.

(3) Growth properties: the bacteria are cultured in MRS medium for about 18 hours at constant temperature of 37° C. to reach log phase.

(4) Good tolerance to simulate gastrointestinal fluid.

(5) Significantly improve pathological tissue damages such as liver, duodenum and so on of rat with from metabolic syndrome.

(6) Significantly improve oral glucose tolerance of rat with metabolic syndrome.

(7) Decrease area under the curve in glucose tolerance test.

(8) Regulate the levels of triglyceride and total cholesterol in serum back to normal level.

(9) Increase 5-hydroxytryptamine (5-HT) level in peripheral blood and regulate testosterone to normal level.

(10) Significantly recover abundances of Bifidobacterium genus, Turicibacter genus, Oscillospira genus, Blautia genus and so on in abnormal intestinal flora caused by high-fat high-starch diet.

The strain CCFM8631 of Lactobacillus reuteri of the present disclosure is obtained by the following method.

I. Isolation and Screening of Lactobacillus

(1) 1 g of fresh feces was diluted in gradient, spreaded on Lactobacillus highly selected solid medium plates (0.05 g bromocresol green, 0.02 g vancomycin, 20 g agar per 1 L MRS medium, pH 5.0±0.1), and the plates were incubated at 37° C. for 48-72 hours. The feces were obtained from a 57-year-old healthy female in Changshou Village, Bama Town in Guangxi Province, China.

(2) Morphology of the colonies were observed and recorded, and single colony was picked out and purified by streaking.

(3) The bacteria were cultured at 37° C. for 24 hours in MRS medium, and the colonies obtained were subjected to Gram staining. The morphologies of the colonies were recorded.

(4) The Gram-negative strains and Gram-positive cocci were discarded, the Gram-positive bacilli were selected.

(5) The bacteria were subjected to catalase analyzing, the catalase-positive strains were discarded and catalase-negative strains were retained.

II. Molecular Biological Identification of Lactobacillus reuteri

(1) Genome extraction of single bacterium (according to operation procedures of TIANamp Bacteria DNA kit)

A. The Lactobacillus obtained in Step I was cultured overnight. 1 mL culture was put into a 1.5 mL centrifuge tube and centrifuged at 10,000 rpm (˜11,500×g) for 1 minute. The supernatant was removed as much as possible.

B. 180 μL buffer (20 mg/mL lysozyme solution with 20 mM Tris (pH 8.0), 2 mM Na₂-EDTA, and 1.2% Triton) was added to the bacteria and incubated at 37° C. for more than 30 minutes. (The lysozyme solution should be prepared by dissolving lysozyme dry powder in the buffer, or the lysozyme would be inactive.

C. 20 μL Proteinase K solution was added to the tube and mixed well.

D. 220 μL buffer GB was added, shaken for 15 seconds, and placed at 70° C. for 10 minutes. The solution turned clean. The tube was centrifuged for a few seconds to remove water drops on inner wall of the tube.

E. 220 μL absolute alcohol was added adequately shaken for 15 seconds. Flocculent precipitates maybe appear. The tube was centrifuged for a few seconds to remove water drops on inner wall of the tube.

F. The solution and flocculent precipitate obtained in the last step were put into an adsorption column CB3 (the absorption column was disposed in a collecting tube), and subjected to centrifugation at 12,000 rpm (˜13,400×g) for 30 seconds. The flow-through liquor was discarded, and the adsorption column was put back into the collecting tube.

G. 500 μL of buffer GD (check for absolute alcohol adding before use) was added to the adsorption column CB3. The column was centrifuged at 12,000 rpm (˜13,400×g) for 30 seconds. The flow-through liquor was discarded, and the adsorption column was put back into the collecting tube.

H. 600 μL of washing solution PW (check for absolute alcohol adding before use) was added to the adsorption column CB3. The column was centrifuged at 12,000 rpm (˜13,400×g) for 30 seconds. The flow-through liquor was discarded, and the adsorption column was put back into the collecting tube. This step was repeated once.

I. The adsorption column CB3 was put back into the collecting tube, centrifuged at 12,000 rpm (˜13,400×g) for 2 minutes, and the flow-through liquor was discarded. The adsorption column CB3 was placed at room temperature for a few minutes to let the adsorption column totally dry.

J. The adsorption column CB3 was transferred to a clean centrifugal tube, and 50 to 200 μL of elution buffer TE was dropped to the middle of the adsorption film. The adsorption column was placed at room temperature for 2 to 5 minutes, and then centrifuged at 12,000 rpm (˜13,400×g) for 2 minutes. The eluted solution was collected into a centrifuge tube.

(2) Whole Genome Sequencing

The extracted whole genome was sent to a professional sequencing company and a third-generation sequencer was used to sequence the whole bacterial genome. The sequencing results were subjected to similarity comparison by BLAST software among GeneBank database. The results show that the strain provided by the present disclosure is a Lactobacillus reuteri, but different from known Lactobacillus reuteri, so that it is identified as a new strain. By blastn algorithm, the genome of strain CCFM8631 of Lactobacillus reuteri was compared with that of standard strain DSM20016 of Lactobacillus reuteri (https://wwwncbi.nlm.nih.gov/genome/?term=438), 571 genes in total show differences, which are shown in Table 1.

TABLE 1 Differential genes between strain CCFM8631 of Lactobacillus reuteri and standard strain DSM20016 of Lactobacillus reuteri Corre- Database Database nr Database lation Gene Gene Article Article Gene ID Article ID Note of the Results Similarity Length Mismatching Gap Start End Start End E Score TBCP-1560_g_0003 gi|970364679| oxidoreductase, short chain dehydrogenase/ 100 190 0 0 1 570 1 190 6.06E−143 394 emb|CUR36395.1| reductase family [Lactobacillus reuteri] TBCP-1560_g_0004 gi|512154930| short chain dehydrogenase [Lactobacillus 100 44 0 0 1 132 1 44 4.35E−25 85.5 gb|AGN98213.1| reuteri I5007] TBCP-1560_g_0019 gi|970370732| Transcriptional regulator, XRE family [Lactobacillus 97.059 34 1 0 1 102 1 34 1.46E−17 69.7 emb|CUR40704.1| reuteri] TBCP-1560_g_0020 gi|953265103| Insertion sequence IS232 putative ATP-b 100 245 0 0 1 735 1 245 0 504 emb|CUU12464.1| inding protein [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_0023 gi|512154946| hypothetical protein LRI_0020 [Lactobacillus 100 31 0 0 95 3 7 37 4.49E−16 62 gb|AGN98229.1| reuteri I5007] TBCP-1560_g_0038 gi|518081627| sulfurtransferase [Lactobacillus reuteri] 100 258 0 0 1 774 1 258 0 503 ref|WP_019251835.1| TBCP-1560_g_0051 gi|948618354| OsmC family protein [Lactobacillus reuteri 100 142 0 0 1 426 19 160 3.75E−105 296 gb|KRK50363.1| DSM 20016] TBCP-1560_g_0052 gi|1017201634| lactate dehydrogenase [Lactobacillus reuteri] 99.698 331 1 0 1 993 1 331 0 644 ref|WP_063164307.1| TBCP-1560_g_0054 gi|489766316| hypothetical protein [Lactobacillus reuteri] 100 73 0 0 1 219 1 73 3.14E−41 128 ref|WP_003670244.1| TBCP-1560_g_0069 gi|489771585| GTP pyrophosphokinase [Lactobacillus reuteri] 100 206 0 0 1 618 1 206 1.73E−156 430 ref|WP_003675493.1| TBCP-1560_g_0080 gi|489771566| guanosine monophosphate reductase [Lactobacillus 100 324 0 0 1 972 1 324 0 674 ref|WP_003675474.1| reuteri] TBCP-1560_g_0084 gi|489771562| hypothetical protein [Lactobacillus reuteri] 100 128 0 0 1 384 1 128 3.65E−93 263 ref|WP_003675470.1| TBCP-1560_g_0095 gi|489771550| carbamoyl phosphate synthase large subunit 100 1056 0 0 1 3168 1 1056 0 2122 ref|WP_003675458.1| [Lactobacillus reuteri] TBCP-1560_g_0109 gi|489771532| DNA-binding response regulator [Lactobacillus 100 226 0 0 1 678 1 226 5.55E−155 428 ref|WP_003675440.1| reuteri] TBCP-1560_g_0114 gi|489771525| transcriptional regulator [Lactobacillus reuteri] 100 197 0 0 1 591 1 197 4.60E−149 410 ref|WP_003675433.1| TBCP-1560_g_0115 gi|489771524| hypothetical protein [Lactobacillus reuteri] 100 226 0 0 1 678 1 226 6.77E−170 466 ref|WP_003675432.1| TBCP-1560_g_0116 gi|489771523| NAD-dependent protein deacetylase [Lactobacillus 100 324 0 0 1 972 1 324 0 645 ref|WP_003675431.1| reuteri] TBCP-1560_g_0120 gi|512155047| acetyltransferase [Lactobacillus reuteri I5007] 100 176 0 0 1 528 1 176 1.40E−111 314 gb|AGN98330.1| TBCP-1560_g_0121 gi|489761202| hypothetical protein [Lactobacillus reuteri] 98.507 67 1 0 1 201 1 67 1.44E−44 136 ref|WP_003665145.1| TBCP-1560_g_0122 gi|489771517| cell surface protein [Lactobacillus reuteri] 100 286 0 0 1 858 1 286 0 584 ref|WP_003675425.1| TBCP-1560_g_0123 gi|737175530| phenolic acid decarboxylase padC [Lactobacillus 100 179 0 0 1 537 1 179 3.28E−134 371 ref|WP_035161724.1| reuteri] TBCP-1560_g_0125 gi|337728644| putative NAD binding protein, possible epimerase/ 100 208 0 0 1 624 1 208 7.71E−155 426 emb|CCC03755.1| dehydratase [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_0134 gi|512738680| NADH-flavin reductase-like protein [Lactobacillus 100 214 0 0 1 642 1 214 5.25E−162 444 ref|WP_016496408.1| reuteri] TBCP-1560_g_0135 gi|489765480| HesB/YadR/YfhF-family protein [Lactobacillus 100 120 0 0 1 360 4 123 1.08E−87 249 ref|WP_003669411.1| reuteri] TBCP-1560_g_0136 gi|489765479| glutamine amidotransferase [Lactobacillus 100 223 0 0 1 669 1 223 5.25E−170 466 ref|WP_003669410.1| reuteri] TBCP-1560_g_0139 gi|489771502| diguanylate phosphodiesterase [Lactobacillus 100 211 0 0 1 633 1 211 2.57E−158 436 ref|WP_003675410.1| reuteri] TBCP-1560_g_0148 gi|512738689| hypothetical protein [Lactobacillus reuteri] 95.652 115 5 0 1 345 1 115 6.55E−67 207 ref|WP_016496417.1| TBCP-1560_g_0154 gi|518083879| NAD-dependent dehydratase [Lactobacillus 100 48 0 0 1 144 1 48 6.74E−29 100 ref|WP_019254087.1| reuteri] TBCP-1560_g_0156 gi|489771478| GCN5 family N-acetyltransferase [Lactobacillus 100 145 0 0 1 435 1 145 3.98E−108 303 ref|WP_003675387.1| reuteri] TBCP-1560_g_0158 gi|489761160| cytochrome b5 [Lactobacillus reuteri] 100 72 0 0 1 216 1 72 2.40E−47 143 ref|WP_003665104.1| TBCP-1560_g_0159 gi|489771474| cytochrome b5 [Lactobacillus reuteri] 100 81 0 0 1 243 1 81 3.19E−57 169 ref|WP_003675383.1| TBCP-1560_g_0161 gi|337728616| hypothetical protein LRATCC53608_0972 100 38 0 0 1 114 1 38 6.70E−21 74.7 emb|CCC03724.1| [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_0180 gi|489771454| TetR family transcriptional regulator [Lactobacillus 100 170 0 0 1 510 1 170 3.30E−127 353 ref|WP_003675363.1| reuteri] TBCP-1560_g_0184 gi|489771446| hypothetical protein [Lactobacillus reuteri] 100 78 0 0 1 234 1 78 2.35E−55 164 ref|WP_003675355.1| TBCP-1560_g_0190 gi|489771434| hypothetical protein [Lactobacillus reuteri] 100 206 0 0 1 618 1 206 5.91E−156 429 ref|WP_003675343.1| TBCP-1560_g_0192 gi|489771430| histidine--tRNA ligase [Lactobacillus reuteri] 100 425 0 0 1 1275 1 425 0 836 ref|WP_003675339.1| TBCP-1560_g_0197 gi|227186376| hypothetical protein HMPREF0534_0218 94.231 52 3 0 1 156 1 52 1.84E−30 99.8 gb|EEI66447.1| [Lactobacillus reuteri CF48-3A] TBCP-1560_g_0199 gi|489765400| hypothetical protein [Lactobacillus reuteri] 99.541 218 1 0 1 654 1 218 1.28E−165 454 ref|WP_003669331.1| TBCP-1560_g_0200 gi|526246046| hypothetical protein [Lactobacillus reuteri] 100 39 0 0 1 117 1 39 4.20E−17 67 ref|WP_020843400.1| TBCP-1560_g_0208 gi|512155129| C4-dicarboxylate anaerobic carrier [Lactobacillus 98.592 71 1 0 1 213 1 71 2.23E−48 146 gb|AGN98412.1| reuteri I5007] TBCP-1560_g_0216 gi|489771396| RNA pseudouridine synthase [Lactobacillus 100 306 0 0 1 918 1 306 0 630 ref|WP_003675305.1| reuteri] TBCP-1560_g_0217 gi|526246038| membrane protein [Lactobacillus reuteri] 99.203 251 2 0 1 753 1 251 5.51E−174 478 ref|WP_020843392.1| TBCP-1560_g_0220 gi|512738724| signal peptide [Lactobacillus reuteri] 99.914 1166 1 0 1 3498 1 1166 0 2135 ref|WP_016496451.1| TBCP-1560_g_0227 gi|1017201665| patatin family protein [Lactobacillus reuteri] 100 74 0 0 1 222 1 74 2.62E−50 151 ref|WP_063164338.1| TBCP-1560_g_0229 gi|754210084| hypothetical protein [Lactobacillus reuteri] 100 100 0 0 1 300 1 100 2.00E−70 204 ref|WP_041821572.1| TBCP-1560_g_0231 gi|489771374| membrane protein [Lactobacillus reuteri] 99.614 259 1 0 1 777 1 259 0 535 ref|WP_003675283.1| TBCP-1560_g_0237 gi|512155158| hypothetical protein LRI_0232 [Lactobacilitis 100 61 0 0 1 183 1 61 2.47E−41 127 gb|AGN98441.1| reuteri I5007] TBCP-1560_g_0240 gi|489761065| hypothetical protein [Lactobacillus reuteri] 100 106 0 0 1 318 1 106 3.15E−76 219 ref|WP_003665009.1| TBCP-1560_g_0241 gi|970363723| Glutathione-regulated potassium-efflux system 100 227 0 0 1 681 1 227 3.80E−149 413 emb|CUR37285.1| ancillary protein KefG [Lactobacillus reuteri] TBCP-1560_g_0242 gi|337728551| hypothetical protein LRATCC53608_0905 100 57 0 0 1 171 1 57 5.59E−38 119 emb|CCC03657.1| [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_0245 gi|489771350| ATPase [Lactobacillus reuteri] 99.738 381 1 0 1 1143 1 381 0 771 ref|WP_003675259.1| TBCP-1560_g_0246 gi|489771348| peptidase [Lactobacillus reuteri] 99.535 430 2 0 1 1290 1 430 0 850 ref|WP_003675257.1| TBCP-1560_g_0248 gi|489771344| peptidase M13 [Lactobacillus reuteri] 99.685 634 2 0 1 1902 1 634 0 1298 ref|WP_003675253.1| TBCP-1560_g_0249 gi|512738735| transcriptional regulator [Lactobacillus reuteri] 99.528 212 1 0 1 636 1 212 5.98E−157 432 ref|WP_016496462.1| TBCP-1560_g_0250 gi|489771340| RNase III inhibitor [Lactobacillus reuteri] 99.401 167 1 0 1 501 1 167 2.83E−124 345 ref|WP_003675249.1| TBCP-1560_g_0255 gi|512156691| transposase [Lactobacillus reuteri I5007] 96.552 29 1 0 1 87 14 42 1.86E−15 60.5 gb|AGN99974.1| TBCP-1560_g_0276 gi|970366323| Proton/glutamate symport protein @ Sodium/ 99.771 437 1 0 1 1311 1 437 0 842 emb|CUR42817.1| glutamate symport protein [Lactobacillus reuteri] TBCP-1560_g_0279 gi|512738751| low temperature requirement protein LtrA 100 123 0 0 4 372 2 124 1.04E−86 247 ref|WP_016496478.1| [Lactobacillus reuteri] TBCP-1560_g_0280 gi|489765927| hypothetical protein [Lactobacillus reuteri] 100 175 0 0 1 525 35 209 1.27E−113 320 ref|WP_003669856.1| TBCP-1560_g_0291 gi|512738759| ABC transporter ATP-binding protein [Lactobacillus 99.303 287 2 0 1 861 1 287 0 586 ref|WP_016496485.1| reuteri] TBCP-1560_g_0292 gi|337728515| hypothetical protein LRATCC53608_0867 99.425 174 1 0 1 522 5 178 1.84E−127 354 emb|CCC03619.1| [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_0293 gi|659900074| hypothetical protein LR3_04370 [Lactobacillus 100 193 0 0 1 579 1 193 1.28E−122 343 gb|KEK14882.1| reuteri] TBCP-1560_g_0294 gi|489760987| MarR family transcriptional regulator [Lactobacillus 99.333 150 1 0 1 450 1 150 1.06E−107 302 ref|WP_003664931.1| reuteri] TBCP-1560_g_0295 gi|489765281| hypothetical protein [Lactobacillus reuteri] 100 241 0 0 1 723 1 241 6.83E−175 479 ref|WP_003669212.1| TBCP-1560_g_0298 gi|754210095| hypothetical protein [Lactobacillus reuteri] 99.333 300 2 0 1 900 12 311 0 506 ref|WP_041821582.1| TBCP-1560_g_0300 gi|489760978| glycerol transporter [Lactobacillus reuteri] 100 235 0 0 1 705 1 235 2.25E−169 465 ref|WP_003664922.1| TBCP-1560_g_0302 gi|512738768| ABC transporter-like protein [Lactobacillus 99.655 580 2 0 1 1740 1 580 0 1146 ref|WP_016496494.1| reuteri] TBCP-1560_g_0307 gi|489771190| GntR family transcriptional regulator [Lactobacillus 100 243 0 0 1 729 1 243 1.74E−179 491 ref|WP_003675099.1| reuteri] TBCP-1560_g_0308 gi|489771188| phosphoketolase [Lactobacillus reuteri] 100 803 0 0 1 2409 1 803 0 1671 ref|WP_003675097.1| TBCP-1560_g_0311 gi|489771184| alpha/beta hydrolase [Lactobacillus reuteri] 100 248 0 0 1 744 1 248 0 509 ref|WP_003675093.1| TBCP-1560_g_0313 gi|489771181| transcriptional regulator [Lactobacillus reuteri] 100 300 0 0 1 900 1 300 0 595 ref|WP_003675090.1| TBCP-1560_g_0316 gi|489771178| lipoate--protein ligase A [Lactobacillus reuteri] 100 337 0 0 1 1011 1 337 0 699 ref|WP_003675087.1| TBCP-1560_g_0318 gi|489765148| hypothetical protein [Lactobacillus reuteri] 100 152 0 0 1 456 1 152 9.65E−111 310 ref|WP_003669080.1| TBCP-1560_g_0320 gi|489771175| PTS galactitol transporter subunit IIC [Lactobacillus 100 470 0 0 1 1410 1 470 0 895 ref|WP_003675084.1| reuteri] TBCP-1560_g_0324 gi|737175460| alpha/beta hydrolase [Lactobacillus reuteri] 99.693 326 1 0 1 978 1 326 0 634 ref|WP_035161655.1| TBCP-1560_g_0325 gi|489760939| membrane protein [Lactobacillus reuteri] 100 118 0 0 1 354 1 118 6.50E−68 199 ref|WP_003664884.1| TBCP-1560_g_0334 gi|489771154| ferredoxin--NADP(+) reductase [Lactobacillus 100 332 0 0 1 996 1 332 0 681 ref|WP_003675063.1| reuteri] TBCP-1560_g_0346 gi|489765111| spermidine/purescine ABC transporter permease 100 272 0 0 1 816 1 272 0 516 ref|WP_003669043.1| [Lactobacillus reuteri] TBCP-1560_g_0347 gi|489771138| spermidine/putrescine ABC transporter substrate- 100 357 0 0 1 1071 1 357 0 687 ref|WP_003675047.1| binding protein [Lactobacillus reuteri] TBCP-1560_g_0352 gi|489771133| guanylate kinase [Lactobacillus reuteri] 100 190 0 0 1 570 1 190 4.51E−143 395 ref|WP_003675042.1| TBCP-1560_g_0354 gi|489760888| hypothetical protein [Lactobacillus reuteri] 99.206 126 1 0 1 378 1 126 4.36E−46 147 ref|WP_003664833.1| TBCP-1560_g_0361 gi|953264637| CsbD family protein [Lactobacillus reuteri 100 61 0 0 1 183 1 61 1.12E−08 45.4 emb|CUU11948.1| ATCC 53608] TBCP-1560_g_0370 gi|489771105| type I pantothenate kinase [Lactobacillus 100 307 0 0 1 921 1 307 0 630 ref|WP_003675014.1| reuteri] TBCP-1560_g_0380 gi|337728374| conserved hypothetical protein [Lactobacillus 100 204 0 0 1 612 4 207 4.94E−152 419 emb|CCC03475.1| reuteri ATCC 53608] TBCP-1560_g_0381 gi|489760823| peptidase M10 [Lactobacillus reuteri] 100 231 0 0 1 693 1 231 2.95E−138 386 ref|WP_003664768.1| TBCP-1560_g_0384 gi|194454116| hypothetical protein Lreu23DRAFT_4532 92.683 41 3 0 1 123 1 41 2.22E−22 78.6 gb|EDX43013.1| [Lactobacillus reuteri 100-23] TBCP-1560_g_0387 gi|512155310| membrane protein [Lactobacillus reuteri 100 369 0 0 1 1107 1 369 0 515 gb|AGN98593.1| I5007] TBCP-1560_g_0388 gi|489760812| elongation factor P [Lactobacillus reuteri] 100 185 0 0 1 555 1 185 3.22E−136 377 ref|WP_003664757.1| TBCP-1560_g_0389 gi|489760811| hypothetical protein [Lactobacillus reuteri] 97.714 350 8 0 1 1050 1 350 0 573 ref|WP_003664756.1| TBCP-1560_g_0394 gi|970366169| FIG00746573: hypothetical protein [Lactobacillus 100 338 0 0 1 1014 1 338 0 699 emb|CUR43008.1| reuteri] TBCP-1560_g_0396 gi|737167860| hypothetical protein [Lactobacillus reuteri] 89.313 131 14 0 1 393 1 131 1.12E−84 242 ref|WP_035154108.1| TBCP-1560_g_0399 gi|1016922021| phosphate ABC transporter substrate-binding 100 290 0 0 1 870 1 290 0 591 gb|AMY14452.1| protein [Lactobacillus reuteri] TBCP-1560_g_0400 gi|489771084| phosphate ABC transporter permease sub 99.666 299 1 0 1 897 1 299 0 530 ref|WP_003674993.1| unit PstC [Lactobacillus reuteri] TBCP-1560_g_0403 gi|227184997| phosphate transport system regulatory protein 100 234 0 0 1 702 10 243 4.44E−174 477 gb|EEI65068.1| PhoU [Lactobacillus reuteri CF48- 3A] TBCP-1560_g_0405 gi|970368823| FIG00748601: hypothetical protein [Lactobacillus 100 287 0 0 1 861 1 287 0 578 emb|CUR38312.1| reuteri] TBCP-1560_g_0406 gi|512155320| hypothetical protein LRI_0394 [Lactobacillus 100 48 0 0 1 144 1 48 3.21E−28 93.6 gb|AGN98603.1| reuteri I5007] TBCP-1560_g_0407 gi|512155321| glycosyl transferase family protein [Lactobacillus 100 227 0 0 1 681 1 227 1.65E−160 442 gb|AGN98604.1| reuteri I5007] TBCP-1560_g_0410 gi|512155324| glycosyltransferase [Lactobacillus reuteri 100 191 0 0 1 573 1 191 5.67E−120 337 gb|AGN98607.1| I5007] TBCP-1560_g_0411 gi|512738819| glycoside hydrolase [Lactobacillus reuteri] 100 379 0 0 1 1137 1 379 0 798 ref|WP_016496544.1| TBCP-1560_g_0414 gi|512738822| potassium uptake protein [Lactobacillus reuteri] 99.776 447 1 0 1 1341 1 447 0 823 ref|WP_016496547.1| TBCP-1560_g_0416 gi|970368831| FIG00748017: hypothetical protein [Lactobacillus 100 164 0 0 52 543 18 181 7.57E−118 330 emb|CUR38320.1| reuteri] TBCP-1560_g_0420 gi|970367179| Cystathionine beta-synthase [Lactobacillus 100 304 0 0 1 912 1 304 0 531 emb|CUR39802.1| reuteri] TBCP-1560_g_0423 gi|970367177| Inner membrane protein [Lactobacillus reuteri] 100 339 0 0 1 1017 4 342 0 585 emb|CUR39800.1| TBCP-1560_g_0425 gi|512738831| esterase [Lactobacillus reuteri] 100 238 0 0 1 714 1 238 4.41E−180 492 ref|WP_016496555.1| TBCP-1560_g_0430 gi|489771049| hypothetical protein [Lactobacillus reuteri] 100 444 0 0 1 1332 1 444 0 917 ref|WP_003674958.1| TBCP-1560_g_0431 gi|489771047| MFS transporter permease [Lactobacillus 100 405 0 0 1 1215 1 405 0 664 ref|WP_003674956.1| reuteri] TBCP-1560_g_0435 gi|512155348| D-alanyl-D-alanine carboxypeptidase [Lactobacillus 100 417 0 0 1 1251 1 417 0 768 gb|AGN98631.1| reuteri I5007] TBCP-1560_g_0440 gi|512738842| transposase [Lactobacillus reuteri] 100 386 0 0 1 1158 1 386 0 806 ref|WP_016496566.1| TBCP-1560_g_0441 gi|953264694| hypothetical protein LRATCC53608_0483 99.643 561 2 0 1 1683 1 561 0 1136 emb|CUU12019.1| [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_0443 gi|489771033| peptidyl-prolyl cis-trans isomerase [Lactobacillus 100 186 0 0 1 558 1 186 3.90E−128 357 ref|WP_003674942.1| reuteri] TBCP-1560_g_0445 gi|1017201710| NAD-dependent malic enzyme [Lactobacillus 100 542 0 0 1 1626 1 542 0 1083 ref|WP_063164383.1| reuteri] TBCP-1560_g_0447 gi|489771029| flavocytochrome c [Lactobacillus reuteri] 100 464 0 0 1 1392 1 464 0 944 ref|WP_003674938.1| TBCP-1560_g_0450 gi|227185979| putative sugar-binding domain protein [Lactobacillus 98.403 313 5 0 1 939 55 367 0 641 gb|EEI66050.1| reuteri CF48-3A] TBCP-1560_g_0452 gi|227185977| [citrate (pro-3S)-lyase] ligase [Lactobacillus 99.424 347 2 0 1 1041 13 359 0 712 gb|EEI66048.1| reuteri CF48-3A] TBCP-1560_g_0453 gi|489766774| citrate lyase ACP [Lactobacillus reuteri] 100 97 0 0 1 291 1 97 3.27E−67 196 ref|WP_003670701.1| TBCP-1560_g_0454 gi|489766772| citrate (pro-3S)-lyase subunit beta [Lactobacillus 100 301 0 0 1 903 1 301 0 598 ref|WP_003670699.1| reuteri] TBCP-1560_g_0456 gi|518082469| triphosphoribosyl-dephospho-CoA synthase 98.737 475 6 0 1 1425 1 475 0 966 ref|WP_019252677.1| [Lactobacillus reuteri] TBCP-1560_g_0457 gi|518082470| hydrolase [Lactobacillus reuteri] 98.099 263 5 0 1 789 1 263 0 538 ref|WP_019252678.1| TBCP-1560_g_0459 gi|489760694| LysR family transcriptional regulator [Lactobacillus 100 295 0 0 1 885 1 295 0 599 ref|WP_003664640.1| reuteri] TBCP-1560_g_0460 gi|489764917| membrane protein [Lactobacillus reuteri] 99.341 455 3 0 1 1365 1 455 0 782 ref|WP_003668849.1| TBCP-1560_g_0461 gi|737167582| uracil-DNA glycosylase [Lactobacillus reuteri] 99.078 217 2 0 1 651 1 217 2.67E−161 443 ref|WP_035153834.1| TBCP-1560_g_0463 gi|489771024| alpha/beta hydrolase [Lactobacillus reuteri] 99.694 327 1 0 1 981 1 327 0 679 ref|WP_003674933.1| TBCP-1560_g_0466 gi|336448233| pseudouridine synthase, RluA family [Lactobacillus 100 290 0 0 1 870 26 315 0 604 gb|AEI56848.1| reuteri SD2112] TBCP-1560_g_0469 gi|489764899| MerR family transcriptional regulator [Lactobacillus 100 148 0 0 1 444 1 148 1.45E−107 301 ref|WP_003668831.1| reuteri] TBCP-1560_g_0470 gi|489771016| hypothetical protein [Lactobacillus reuteri] 99.13 115 1 0 1 345 1 115 1.63E−82 236 ref|WP_003674926.1| TBCP-1560_g_0471 gi|489771015| RNase J family beta-CASP ribonuclease 100 618 0 0 1 1854 1 618 0 1281 ref|WP_003674925.1| [Lactobacillus reuteri] TBCP-1560_g_0472 gi|970364104| FIG00743019: hypothetical protein [Lactobacillus 100 395 0 0 1 1185 1 395 0 757 emb|CUR36934.1| reuteri] TBCP-1560_g_0477 gi|489764884| universal stress protein UspA [Lactobacillus 100 158 0 0 1 474 1 158 2.14E−115 322 ref|WP_003668816.1| reuteri] TBCP-1560_g_0479 gi|489771009| membrane protein [Lactobacillus reuteri] 100 230 0 0 1 690 1 230 1.11E−144 402 ref|WP_003674919.1| TBCP-1560_g_0482 gi|489760658| cold-shock protein [Lactobacillus reuteri] 100 66 0 0 1 198 1 66 8.39E−44 134 ref|WP_003664604.1| TBCP-1560_g_0485 gi|489764871| phosphatase [Lactobacillus reuteri] 100 224 0 0 1 672 1 224 1.46E−159 439 ref|WP_003668803.1| TBCP-1560_g_0486 gi|489771002| N-acetyltransferase GCN5 [Lactobacillus 100 151 0 0 1 453 1 151 9.53E−112 312 ref|WP_003674912.1| reuteri] TBCP-1560_g_0489 gi|970366045| membrane protein [Lactobacillus reuteri] 93.627 204 11 1 7 612 34 237 1.97E−144 400 emb|CUR43096.1| TBCP-1560_g_0490 gi|512155402| membrane protein [Lactobacillus reuteri 100 48 0 0 1 144 1 48 4.28E−29 101 gb|AGN9868 5.1| I5007] TBCP-1560_g_0491 gi|512155403| membrane protein [Lactobacillus reuteri 100 47 0 0 1 141 1 47 3.79E−30 98.6 gb|AGN98686.1| I5007] TBCP-1560_g_0493 gi|227071188| transcriptional repressor of CtsR [Lactobacillus 100 155 0 0 1 465 13 167 3.41E−98 279 gb|EEI09504.1| reuteri MM2-3] TBCP-1560_g_0500 gi|489760630| 30S ribosomal protein S12 [Lactobacillus 100 139 0 0 1 417 1 139 5.65E−88 251 ref|WP_003664576.1| reuteri] TBCP-1560_g_0501 gi|489764856| 30S ribosomal protein S7 [Lactobacillus 100 156 0 0 1 468 1 156 1.98E−116 325 ref|WP_003668788.1| reuteri] TBCP-1560_g_0504 gi|489760623| 30S ribosomal protein S10 [Lactobacillus 100 102 0 0 1 306 1 102 1.43E−70 204 ref|WP_003664569.1| reuteri] TBCP-1560_g_0505 gi|489760621| 50S ribosomal protein L3 [Lactobacillus 100 219 0 0 1 657 1 219 1.69E−148 411 ref|WP_003664567.1| reuteri] TBCP-1560_g_0506 gi|489760620| 50S ribosomal protein L4 [Lactobacillus 100 207 0 0 1 621 1 207 1.00E−140 390 ref|WP_003664566.1| reuteri] TBCP-1560_g_0507 gi|489760618| 50S ribosomal protein L23 [Lactobacillus 100 98 0 0 1 294 1 98 1.39E−54 164 ref|WP_003664564.1| reuteri] TBCP-1560_g_0508 gi|489760617| 50S ribosomal protein L2 [Lactobacillus 99.644 281 1 0 1 843 1 281 0 566 ref|WP_003664563.1| reuteri] TBCP-1560_g_0509 gi|489760614| 30S ribosomal protein S19 [Lactobacillus 100 92 0 0 1 276 1 92 1.12E−64 189 ref|WP_003664560.1| reuteri] TBCP-1560_g_0510 gi|489770978| 50S ribosomal protein L22 [Lactobacillus 100 115 0 0 1 345 1 115 4.01E−78 224 ref|WP_003674888.1| reuteri] TBCP-1560_g_0511 gi_489760610| 30S ribosomal protein S3 [Lactobacillus 99.548 221 1 0 1 663 1 221 4.35E−147 407 ref|WP_003664556.1| reuteri] TBCP-1560_g_0513 gi_489760606| MULTISPECIES: 50S ribosomal protein 100 68 0 0 1 204 1 68 3.61E−43 132 ref|WP_003664552.1| L29 [Lactobacillus] TBCP-1560_g_0514 gi|489760605| 30S ribosomal protein S17 [Lactobacillus 100 88 0 0 1 264 1 88 4.82E−61 179 ref|WP_003664551.1| reuteri] TBCP-1560_g_0516 gi|489760603| 50S ribosomal protein L24 [Lactobacillus 100 102 0 0 1 306 1 102 3.16E−69 201 ref|WP_003664549.1| reuteri] TBCP-1560_g_0517 gi|489764852| 50S ribosomal protein L5 [Lactobacillus 100 180 0 0 1 540 1 180 2.58E−132 367 ref|WP_003668784.1| reuteri] TBCP-1560_g_0518 gi|489760600| 30S ribosomal protein S8 [Lactobacillus 100 132 0 0 1 396 1 132 3.69E−94 266 ref|WP_003664546.1| reuteri] TBCP-1560_g_0522 gi|489760595| 50S ribosomal protein L30 [Lactobacillus 100 60 0 0 1 180 1 60 9.81E−39 121 ref|WP_003664541.1| reuteri] TBCP-1560_g_0525 gi|970368280| Adenylate kinase [Lactobacillus reuteri] 100 219 0 0 1 657 1 219 4.25E−165 453 emb|CUR38822.1| TBCP-1560_g_0526 gi|489770966| translation initiation factor IF-1 [Lactobacillus 98.611 72 1 0 1 216 1 72 6.65E−48 145 ref|WP_003674876.1| reuteri] TBCP-1560_g_0527 gi|489760589| 50S ribosomal protein L36 [Lactobacillus 100 39 0 0 1 117 1 39 1.68E−22 78.6 ref|WP_003664535.1| reuteri] TBCP-1560_g_0534 gi|489770957| cobalt ABC transporter ATP-binding protein 100 267 0 0 1 801 1 267 8.36E−167 461 ref|WP_003674867.1| [Lactobacillus reuteri] TBCP-1560_g_0535 gi|489770955| tRNA pseudouridine(38, 39, 40) synthase TruA 100 256 0 0 1 768 1 256 0 529 ref|WP_003674865.1| [Lactobacillus reuteri] TBCP-1560_g_0537 gi|489764839| 30S ribosomal protein S9 [Lactobacillus 100 133 0 0 1 399 1 133 1.04E−94 268 ref|WP_003668771.1| reuteri] TBCP-1560_g_0540 gi|489770952| acetoin reductase [Lactobacillus reuteri] 99.611 257 1 0 1 771 1 257 0 515 ref|WP_003674862.1| TBCP-1560_g_0542 gi|489770949| xanthine phosphoribosyltransferase [Lactobacillus 100 191 0 0 1 573 1 191 1.21E−129 361 ref|WP_003674859.1| reuteri] TBCP-1560_g_0543 gi|489770948| phosphoribosylaminoimidazole carboxylase 99.735 377 1 0 1 1131 1 377 0 773 ref|WP_003674858.1| [Lactobacillus reuteri] TBCP-1560_g_0544 gi|489760563| ATP-dependent DNA helicase PcrA [Lactobacillus 99.868 757 1 0 1 2271 1 757 0 1530 ref|WP_003664509.1| reuteri] TBCP-1560_g_0546 gi|489770944| CamS family sex pheromone protein [Lactobacillus 99.73 371 1 0 1 1113 1 371 0 681 ref|WP_003674854.1| reuteri] TBCP-1560_g_0547 gi|489770942| asparaginyl/glutamyl-tRNA amidotransferase 100 105 0 0 1 315 1 105 2.86E−73 211 ref|WP_003674852.1| subunit C [Lactobacillus reuteri] TBCP-1560_g_0553 gi|489764819| 23S rRNA (uracil-5-)-methyltransferase RumA 98.954 478 5 0 1 1434 1 478 0 974 ref|WP_003668751.1| [Lactobacillus reuteri] TBCP-1560_g_0560 gi|489767756| preprotein translocase subunit TatB [Lactobacillus 89.011 91 10 0 1 273 88 178 8.68E−56 169 ref|WP_003671680.1| reuteri] TBCP-1560_g_0562 gi|489767761| hypothetical protein [Lactobacillus reuteri] 100 103 0 0 1 309 1 103 9.66E−63 186 ref|WP_003671685.1| TBCP-1560_g_0564 gi|512155472| hypothetical protein LRI_0546 [Lactobacillus 99.213 127 1 0 1 381 1 127 3.88E−92 261 gb|AGN98755.1| reuteri I5007] TBCP-1560_g_0567 gi|970364147| Lead, cadmium, zinc and mercury transporting 99.21 633 5 0 1 1899 1 633 0 1215 emb|CUR36896.1| ATPase; Copper-translocating P-type ATPase [Lactobacillus reuteri] TBCP-1560_g_0568 gi|489767767| MULTISPECIES: copper-binding protein [Lactobacillus] 100 76 0 0 1 228 1 76 4.09E−51 153 ref|WP_003671691.1| TBCP-1560_g_0569 gi|489770925| DNA-binding protein [Lactobacillus reuteri] 100 181 0 0 1 543 1 181 3.88E−132 366 ref|WP_003674835.1| TBCP-1560_g_0570 gi|953264799| CRP/FNR family transcriptional regulator 99.052 211 2 0 1 633 4 214 8.52E−154 424 emb|CUU12130.1| [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_0574 gi|512155481| DNA-binding protein [Lactobacillus reuteri 98.876 89 1 0 1 267 1 89 3.86E−60 177 gb|AGN98764.1| I5007] TBCP-1560_g_0575 gi|512155482| DNA-binding protein [Lactobacillus reuteri 100 39 0 0 76 192 1 39 3.82E−23 81.6 gb|AGN98765.1| I5007] TBCP-1560_g_0583 gi|337728224| conserved hypothetical protein [Lactobacillus 100 441 0 0 1 1323 1 441 0 904 emb|CCC03316.1| reuteri ATCC 53608] TBCP-1560_g_0584 gi|489770905| hypothetical protein [Lactobacillus reuteri] 100 237 0 0 1 711 1 237 1.80E−179 491 ref|WP_003674815.1| TBCP-1560_g_0586 gi|489770902| nitroreductase [Lactobacillus reuteri] 100 217 0 0 1 651 1 217 1.28E−166 456 ref|WP_003674812.1| TBCP-1560_g_0593 gi|489770891| GCN5 family N-acetyltransferase [Lactobacillus 100 169 0 0 1 507 1 169 8.64E−129 357 ref|WP_003674801.1| reuteri] TBCP-1560_g_0596 gi|489770885| N-acetyltransferase GCN5 [Lactobacillus 100 151 0 0 1 453 1 151 9.54E−101 285 ref|WP_003674795.1| reuteri] TBCP-1560_g_0598 gi|489770881| glutamate-cysteine ligase [Lactobacillus 100 509 0 0 1 1527 1 509 0 1053 ref|WP_003674791.1| reuteri] TBCP-1560_g_0600 gi|489770878| Rossman fold protein, TIGR00730 family 99.476 191 1 0 1 573 1 191 5.66E−144 397 ref|WP_003674788.1| [Lactobacillus reuteri] TBCP-1560_g_0604 gi|489770875| helicase [Lactobacillus reuteri] 99.307 433 3 0 1 1299 1 433 0 846 ref|WP_003674785.1| TBCP-1560_g_0609 gi|489764752| type I methionyl aminopeptidase [Lactobacillus 100 285 0 0 1 855 1 285 0 524 ref|WP_003668684.1| reuteri] TBCP-1560_g_0612 gi|489770861| glutamate/gamma-aminobutyrate family transporter 99.8 501 1 0 1 1503 1 501 0 945 ref|WP_003674771.1| YjeM [Lactobacillus reuteri] TBCP-1560_g_0613 gi|489770858| hypothetical protein [Lactobacillus reuteri] 100 296 0 0 1 888 1 296 0 571 ref|WP_003674768.1| TBCP-1560_g_0617 gi|489770854| exopolysaccharide biosynthesis protein [Lactobacillus 99.216 255 2 0 1 765 1 255 0 498 ref|WP_003674764.1| reuteri] TBCP-1560_g_0621 gi|489770847| hypothetical protein [Lactobacillus reuteri] 100 473 0 0 1 1419 1 473 0 915 ref|WP_003674757.1| TBCP-1560_g_0623 gi|489770844| hypothetical protein [Lactobacillus reuteri] 100 343 0 0 1 1029 1 343 0 699 ref|WP_003674754.1| TBCP-1560_g_0625 gi|953264848| hypothetical protein predicted by prodigal 100 41 0 0 1 123 1 41 4.54E−22 77.8 emb|CUU12186.1| [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_0634 gi|489770828| hypothetical protein [Lactobacillus reuteri] 100 190 0 0 1 570 1 190 8.04E−70 209 ref|WP_003674738.1| TBCP-1560_g_0638 gi|737169510| hypothetical protein [Lactobacillus reuteri] 84.314 51 8 0 1 153 351 401 4.85E−24 90.9 ref|WP_035155744.1| TBCP-1560_g_0642 gi|526245865| AI-2E family transporter [Lactobacillus reuteri] 99.731 372 1 0 1 1116 1 372 0 580 ref|WP_020843219.1| TBCP-1560_g_0644 gi|489770813| glycosyl transferase family 2 [Lactobacillus 100 239 0 0 1 717 1 239 1.92E−163 450 ref|WP_003674724.1| reuteri] TBCP-1560_g_0658 gi|1017201776| hypothetical protein [Lactobacillus reuteri] 96.889 225 7 0 1 675 1 225 3.13E−113 322 ref|WP_063164449.1| TBCP-1560_g_0663 gi|489770795| hypothetical protein [Lactobacillus reuteri] 100 61 0 0 1 183 1 61 5.63E−41 126 ref|WP_003674706.1| TBCP-1560_g_0664 gi|489760395| phosphocarrier protein HPr [Lactobacillus 100 88 0 0 1 264 1 88 2.79E−60 177 ref|WP_003664342.1| reuteri] TBCP-1560_g_0667 gi|512738944| glycosyl transferase [Lactobacillus reuteri] 99.708 342 1 0 1 1026 1 342 0 711 ref|WP_016496666.1| TBCP-1560_g_0669 gi|489760389| hypothetical protein [Lactobacillus reuteri] 98.78 82 1 0 1 246 1 82 3.49E−55 164 ref|WP_003664336.1| TBCP-1560_g_0670 gi|970368806| FIG00742798: hypothetical protein [Lactobacillus 98.913 184 2 0 1 552 1 184 1.61E−138 383 emb|CUR38328.1| reuteri] TBCP-1560_g_0674 gi|512738946| anaerobic ribonucleoside triphosphate reductase 99.866 744 1 0 1 2232 1 744 0 1570 ref|WP_016496668.1| [Lactobacillus reuteri] TBCP-1560_g_0675 gi|489766847| anaerobic ribonucleoside-triphosphate reductase 99.479 192 1 0 1 576 1 192 1.08E−144 399 ref|WP_003670774.1| activating protein [Lactobacillus reuteri] TBCP-1560_g_0676 gi|489771954| hypothetical protein [Lactobacillus reuteri] 100 296 0 0 1 888 1 296 0 615 ref|WP_003675859.1| TBCP-1560_g_0678 gi|489771950| phosphoenolpyruvate carboxykinase [Lactobacillus 100 566 0 0 1 1698 1 566 0 1144 ref|WP_003675855.1| reuteri] TBCP-1560_g_0682 gi|489760280| dihydropyrimidine dehydrogenase subunit 100 432 0 0 1 1296 1 432 0 900 ref|WP_003664227.1| B [Lactobacillus reuteri] TBCP-1560_g_0686 gi|1017201782| hypothetical protein [Lactobacillus reuteri] 100 147 0 0 1 441 1 147 1.53E−109 306 ref|WP_063164455.1| TBCP-1560_g_0693 gi|489771933| 3-methyladenine DNA glycosylase [Lactobacillus 100 179 0 0 1 537 1 179 2.08E−136 377 ref|WP_003675838.1| reuteri] TBCP-1560_g_0697 gi|512738953| MOP superfamily multidrug/oligosaccharidyl- 100 549 0 0 1 1647 1 549 0 1082 ref|WP_016496675.1| lipid/poly saccharide flippase transporter [Lactobacillus reuteri] TBCP-1560_g_0699 gi|970363487| Acetylornithine deacetylase/Succinyl-diaminopimelate 100 463 0 0 1 1389 5 467 0 949 emb|CUR37516.1| desuccinylase and related deacylases [Lactobacillus reuteri] TBCP-1560_g_0703 gi|489771917| hypothetical protein [Lactobacillus reuteri] 100 202 0 0 1 606 1 202 2.15E−152 419 ref|WP_003675822.1| TBCP-1560_g_0704 gi|489771915| LacI family transcriptional regulator [Lactobacillus 100 338 0 0 1 1014 1 338 0 694 ref|WP_003675820.1| reuteri] TBCP-1560_g_0706 gi|489764600| hypothetical protein [Lactobacillus reuteri] 100 81 0 0 1 243 1 81 4.84E−54 161 ref|WP_003668533.1| TBCP-1560_g_0707 gi|489771912| abortive infection protein [Lactobacillus 100 225 0 0 1 675 1 225 1.39E−155 429 ref|WP_003675817.1| reuteri] TBCP-1560_g_0708 gi|489760247| hypothetical protein [Lactobacillus reuteri] 100 92 0 0 1 276 1 92 3.18E−65 190 ref|WP_003664194.1| TBCP-1560_g_0710 gi|489771901| 2-amino-4-hydroxy-6-hydroxymethyldihydropteridine 100 170 0 0 1 510 1 170 3.41E−127 353 ref|WP_003675807.1| pyrophosphokinase [Lactobacillus reuteri] TBCP-1560_g_0711 gi|512738959| GTP cyclohydrolase I FolE [Lactobacillus 100 192 0 0 1 576 1 192 2.48E−145 400 ref|WP_016496681.1| reuteri] TBCP-1560_g_0712 gi|489771897| bifunctional folylpolyglutamate synthase/dihydrofolate 99.761 419 1 0 1 1257 1 419 0 828 ref|WP_003675803.1| synthase [Lactobacillus reuteri] TBCP-1560_g_0713 gi|1017201785| non-canonical purine NTP pyrophosphatase 100 195 0 0 1 585 1 195 1.39E−145 401 ref|WP_063164458.1| [Lactobacillus reuteri] TBCP-1560_g_0716 gi|970368862| FIG00745914: hypothetical protein [Lactobacillus 96.667 90 3 0 1 270 1 90 1.02E−48 148 emb|CUR38275.1| reuteri] TBCP-1560_g_0724 gi|737170764| peptidylprolyl isomerase [Lactobacillus reuteri] 99.658 292 1 0 1 876 1 292 0 553 ref|WP_035156980.1| TBCP-1560_g_0727 gi|489766912| multidrug ABC transporter ATP-binding 100 245 0 0 1 735 1 245 0 502 ref|WP_003670839.1| protein [Lactobacillus reuteri] TBCP-1560_g_0729 gi|489760201| tRNA (guanosine(46)-N7)-methyltransferase 99.531 213 1 0 1 639 1 213 1.20E−146 405 ref|WP_003664148.1| TrmB [Lactobacillus reuteri] TBCP-1560_g_0731 gi|512155633| YSIRK Gram-positive signal peptide [Lactobacillus 100 97 0 0 1 291 1 97 9.51E−54 161 gb|AGN98916.1| reuteri I5007] TBCP-1560_g_0732 gi|512155634| LPXTG-motif cell wall anchor domain protein 99.038 104 1 0 1 312 1 104 6.66E−75 218 gb|AGN98917.1| [Lactobacillus reuteri I5007] TBCP-1560_g_0732 gi|512155634| LPXTG-motif cell wall anchor domain protein 100 20 0 0 303 362 102 121 9.85E−07 44.3 gb|AGN98917.1| [Lactobacillus reuteri I5007] TBCP-1560_g_0733 gi|337728871| hypothetical protein LRATCC53608_1237 99.877 811 1 0 1 2433 1 811 0 1516 emb|CCC03990.1| [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_0740 gi|489771859| tRNA-binding protein [Lactobacillus reuteri] 100 215 0 0 1 645 1 215 2.70E−159 438 ref|WP_003675765.1| TBCP-1560_g_0742 gi|489771857| prevent-host-death family protein [Lactobacillus 100 97 0 0 1 291 1 97 1.50E−67 196 ref|WP_003675763.1| reuteri] TBCP-1560_g_0746 gi|1017201790| DNA polymerase I [Lactobacillus reuteri] 99.887 888 1 0 1 2664 1 888 0 1781 ref|WP_063164463.1| TBCP-1560_g_0747 gi|489771849| DNA-formamidopyrimidine glycosylase 100 276 0 0 1 828 1 276 0 574 ref|WP_003675755.1| [Lactobacillus reuteri] TBCP-1560_g_0748 gi|489771847| dephospho-CoA kinase [Lactobacillus reuteri] 100 199 0 0 1 597 1 199 5.28E−146 403 ref|WP_003675753.1| TBCP-1560_g_0749 gi|489764556| NrdR family transcriptional regulator [Lactobacillus 98.701 154 2 0 1 462 1 154 9.09E−112 313 ref|WP_003668489.1| reuteri] TBCP-1560_g_0751 gi|489771843| primosomal protein Dnal [Lactobacillus reuteri] 99.681 313 1 0 1 939 1 313 0 644 ref|WP_003675749.1| TBCP-1560_g_0752 gi|489760160| translation initiation factor IF-3 [Lactobacillus 100 170 0 0 1 510 1 170 1.23E−111 313 ref|WP_003664107.1| reuteri] TBCP-1560_g_0754 gi|489771841| 50S ribosomal protein L20 [Lactobacillus 100 117 0 0 1 351 1 117 6.34E−81 232 ref|WP_003675747.1| reuteri] TBCP-1560_g_0755 gi|489771839| haloacid dehalogenase [Lactobacillus reuteri] 99.432 176 1 0 1 528 1 176 1.67E−127 354 ref|WP_003675745.1| TBCP-1560_g_0757 gi|489760152| RNA-binding protein [Lactobacillus reuteri] 100 103 0 0 1 309 1 103 1.50E−70 204 ref|WP_003664099.1| TBCP-1560_g_0758 gi|489771836| nicotinate-nicotinamide nucleotide adenyl 99.533 214 1 0 1 642 1 214 1.94E−161 443 ref|WP_003675742.1| yltransferase [Lactobacillus reuteri] TBCP-1560_g_0759 gi|489771834| HD domain-containing protein [Lactobacillus 99.51 204 1 0 1 612 1 204 1.63E−151 417 ref|WP_003675740.1| reuteri] TBCP-1560_g_0761 gi|489771832| SAM-dependent methyltransferase [Lactobacillus 100 246 0 0 1 738 1 246 0 516 ref|WP_003675738.1| reuteri] TBCP-1560_g_0762 gi|337728844| conserved hypothetical protein [Lactobacillus 100 377 0 0 1 1131 1 385 0 732 emb|CCC03963.1| reuteri ATCC 53608] TBCP-1560_g_0763 gi|489760146| DNA-binding protein [Lactobacillus reuteri] 99.459 185 1 0 1 555 1 185 6.15E−123 343 ref|WP_003664093.1| TBCP-1560_g_0764 gi|489760145| 50S ribosomal protein L32 [Lactobacillus 100 59 0 0 1 177 1 59 6.08E−30 99 ref|WP_003664092.1| reuteri] TBCP-1560_g_0767 gi|489771827| two-component sensor histidine kinase [Lactobacillus 100 491 0 0 1 1473 1 491 0 946 ref|WP_003675733.1| reuteri] TBCP-1560_g_0768 gi|489771825| glutamate/gamma-aminobutyrate family transporter 99.799 497 1 0 1 1491 1 497 0 941 ref|WP_003675731.1| YjeM [Lactobacillus reuteri] TBCP-1560_g_0774 gi|489764526| hydrolase [Lactobacillus reuteri] 100 168 0 0 1 504 1 168 3.12E−112 315 ref|WP_003668459.1| TBCP-1560_g_0775 gi|489771813| HxlR family transcriptional regulator [Lactobacillus 100 112 0 0 1 336 1 112 7.83E−81 231 ref|WP_003675719.1| reuteri] TBCP-1560_g_0777 gi|512738987| phenylalanine-tRNA ligase subunit beta 100 805 0 0 1 2415 1 805 0 1626 ref|WP_016496708.1| [Lactobacillus reuteri] TBCP-1560_g_0779 gi|489764516| uridine kinase [Lactobacillus reuteri] 100 218 0 0 1 654 1 218 9.30E−115 325 ref|WP_003668449.1| TBCP-1560_g_0782 gi|489771804| heme biosynthesis protein HemY [Lactobacillus 100 129 0 0 1 387 1 129 1.27E−93 265 ref|WP_003675710.1| reuteri] TBCP-1560_g_0785 gi|489760102| MULTISPECIES: 50 S ribosomal protein 100 49 0 0 1 147 1 49 5.01E−31 100 ref|WP_003664049.1| L33 [Lactobacillus] TBCP-1560_g_0786 gi|489771798| 5-formyltetrahydrofolate cyclo-ligase [Lactobacillus 100 184 0 0 1 552 1 184 1.27E−137 380 ref|WP_003675704.1| reuteri] TBCP-1560_g_0789 gi|489764508| hypothetical protein [Lactobacillus reuteri] 100 79 0 0 1 237 1 79 1.19E−53 160 ref|WP_003668441.1| TBCP-1560_g_0793 gi|512738993| tRNA (adenosine(37)-N6)-dimethylallyltransferase 100 307 0 0 1 921 1 307 0 635 ref|WP_016496714.1| MiaA [Lactobacillus reuteri] TBCP-1560_g_0794 gi|489771787| type I glutamate--ammonia ligase [Lactobacillus 100 447 0 0 1 1341 1 447 0 934 ref|WP_003675693.1| reuteri] TBCP-1560_g_0797 gi|194453641| conserved hypothetical protein [Lactobacillus 100 41 0 0 1 123 1 41 1.43E−22 79 gb|EDX42538.1| reuteri 100-23] TBCP-1560_g_0798 gi|512738995| lipoprotein [Lactobacillus reuteri] 99.647 283 1 0 1 849 1 283 0 531 ref|WP_016496716.1| TBCP-1560_g_0799 gi|489771780| peptide-methionine (S)-S-oxide reductase 100 185 0 0 1 555 1 185 2.30E−140 387 ref|WP_003675686.1| [Lactobacillus reuteri] TBCP-1560_g_0802 gi|512738998| hypothetical protein [Lactobacillus reuteri] 100 313 0 0 1 939 1 313 0 638 ref|WP_016496719.1| TBCP-1560_g_0803 gi|489771772| hypothetical protein [Lactobacillus reuteri] 100 168 0 0 1 504 1 168 1.26E−122 341 ref|WP_003675678.1| TBCP-1560_g_0806 gi|489771771| TetR family transcriptional regulator [Lactobacillus 98.039 204 4 0 1 612 1 204 3.44E−148 409 ref|WP_003675677.1| reuteri] TBCP-1560_g_0808 gi|489760062| 50S ribosomal protein L21 [Lactobacillus 100 102 0 0 1 306 1 102 5.16E−57 170 ref|WP_003664009.1| reuteri] TBCP-1560_g_0810 gi|489760059| 50S ribosomal protein L27 [Lactobacillus 100 93 0 0 1 279 1 93 1.32E−64 189 ref|WP_003664006.1| reuteri] TBCP-1560_g_0816 gi|489771761| bifunctional 5,10-methylene-tetrahydrofolate 99.65 286 1 0 1 858 1 286 0 520 ref|WP_003675667.1| dehydrogenase/5,10-methylene-tetrahydrofolate cyclohydrolase [Lactobacillus reuteri] TBCP-1560_g_0819 gi|489771755| farnesyl-diphosphate synthase [Lactobacillus 100 290 0 0 1 870 1 290 0 556 ref|WP_003675661.1| reuteri] TBCP-1560_g_0820 gi|489764469| cell division protein FtsJ [Lactobacillus reuteri] 100 273 0 0 1 819 1 273 0 554 ref|WP_003668402.1| TBCP-1560_g_0821 gi|489771753| ArgR family transcriptional regulator [Lactobacillus 100 150 0 0 1 450 1 150 1.48E−111 312 ref|WP_003675659.1| reuteri] TBCP-1560_g_0822 gi|489771751| DNA repair protein RecN [Lactobacillus 99.821 559 1 0 1 1677 1 559 0 1071 ref|WP_003675657.1| reuteri] TBCP-1560_g_0826 gi|512739002| pantothenate metabolism flavoprotein [Lactobacillus 99.751 401 1 0 1 1203 1 401 0 786 ref|WP_016496722.1| reuteri] TBCP-1560_g_0829 gi|512739004| 16S rRNA (cytosine(967)-C(5))-methyltransferase 99.555 449 2 0 1 1347 1 449 0 886 ref|WP_016496724.1| [Lactobacillus reuteri] TBCP-1560_g_0830 gi|948620368| protein phosphatase 2C-like protein [Lactobacillus 98.467 261 4 0 1 783 1 261 0 527 gb|KRK52332.1| reuteri DSM 20016] TBCP-1560_g_0831 gi|1017201882| protein kinase [Lactobacillus reuteri] 100 634 0 0 1 1902 1 634 0 1305 ref|WP_063164555.1| TBCP-1560_g_0832 gi|489771738| ribosome small subunit-dependent GTPase 99.662 296 1 0 1 888 1 296 0 613 ref|WP_003675644.1| A [Lactobacillus reuteri] TBCP-1560_g_0833 gi|227071790| ribulose-phosphate 3-epimerase [Lactobacillus 100 217 0 0 1 651 15 231 7.04E−159 437 gb|EEI10079.1| reuteri MM2-3] TBCP-1560_g_0835 gi|948620363| hypothetical protein FC53_GL000029 [Lactobacillus 100 61 0 0 1 183 22 82 8.69E−40 124 gb|KRK52327.1| reuteri DSM 20016] TBCP-1560_g_0836 gi|227185635| hypothetical protein HMPREF0534_0958 100 120 0 0 1 360 3 122 2.50E−82 236 gb|EEI65706.1| [Lactobacillus reuteri CF48-3A] TBCP-1560_g_0839 gi|1017201886| phosphate acyltransferase [Lactobacillus reuteri] 100 343 0 0 1 1029 1 343 0 694 ref|WP_063164559.1| TBCP-1560_g_0844 gi|489759870| DNA-binding protein [Lactobacillus reuteri] 100 113 0 0 1 339 1 113 1.34E−79 228 ref|WP_003663818.1| TBCP-1560_g_0846 gi|489759868| 30S ribosomal protein S16 [Lactobacillus 98.901 91 1 0 1 273 1 91 3.03E−64 187 ref|WP_003663816.1| reuteri] TBCP-1560_g_0847 gi|489771725| RNA-binding protein [Lactobacillus reuteri] 100 86 0 0 1 258 1 86 1.89E−58 172 ref|WP_003675631.1| TBCP-1560_g_0848 gi|970363287| 16S rRNA processing protein RimM [Lactobacillus 100 168 0 0 1 504 1 168 5.18E−110 309 emb|CUR37646.1| reuteri] TBCP-1560_g_0851 gi|148531407| LSU ribosomal protein L19P [Lactobacillus 100 128 0 0 1 384 1 128 5.23E−90 256 gb|ABQ83406.1| reuteri DSM 20016] TBCP-1560_g_0853 gi|337728756| hypothetical protein LRATCC53608_1122 100 110 0 0 1 330 2 111 1.99E−79 227 emb|CCC03875.1| [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_0854 gi|489771712| exodeoxyribonuclease [Lactobacillus reuteri] 99.636 275 1 0 1 825 1 275 0 573 ref|WP_003675618.1| TBCP-1560_g_0857 gi|518083618| subtype II CRISPR-associated endonuclease 97.682 302 7 0 1 906 1 302 0 610 ref|WP_019253826.1| Cas1 [Lactobacillus reuteri] TBCP-1560_g_0858 gi|518083617| CRISPR-associated endonuclease Cas2 [Lactobacillus 100 101 0 0 1 303 1 101 1.28E−71 207 ref|WP_019253825.1| reuteri] TBCP-1560_g_0859 gi|518083616| type II-A CRISPR-associated protein Csn2 98.206 223 4 0 1 669 1 223 2.39E−163 449 ref|WP_019253824.1| [Lactobacillus reuteri] TBCP-1560_g_0861 gi|489763052| PTS sugar transporter subunit IIA [Lactobacillus 99.507 203 1 0 1 609 1 203 4.87E−121 357 ref|WP_003666989.1| reuteri] TBCP-1560_g_0862 gi|737166902| phosphotransferase enzyme IIA component 96.078 408 16 0 1 1224 233 640 0 768 ref|WP_035153222.1| [Lactobacillus reuteri] TBCP-1560_g_0863 gi|970370498| Beta-galactosidase [Lactobacillus reuteri] 97.173 672 19 0 1 2016 1 672 0 1370 emb|CUR40930.1| TBCP-1560_g_0865 gi|512739014| 1,4-dihydroxy-2-naphthoate polyprenyltransferase 100 299 0 0 1 897 1 299 0 565 ref|WP_016496734.1| [Lactobacillus reuteri] TBCP-1560_g_0868 gi|489771699| metallophosphoesterase [Lactobacillus reuteri] 100 279 0 0 40 876 14 292 0 583 ref|WP_003675605.1| TBCP-1560_g_0869 gi|489763069| 30S ribosomal protein S14 [Lactobacillus 100 89 0 0 1 267 1 89 2.04E−61 180 ref|WP_003667006.1| reuteri] TBCP-1560_g_0871 gi|489761765| hypothetical protein [Lactobacillus reuteri] 100 18 0 0 172 225 213 230 1.92E−06 42.4 ref|WP_003665706.1| TBCP-1560_g_0872 gi|970364325| L-serine dehydratase, beta subunit [Lactobacillus 99.091 220 2 0 1 660 1 220 1.03E−162 447 emb|CUR36723.1| reuteri] TBCP-1560_g_0873 gi|489771691| L-serine dehydratase, iron-sulfur-dependent 100 293 0 0 1 879 1 293 1.60E−174 483 ref|WP_003675597.1| subunit alpha [Lactobacillus reuteri] TBCP-1560_g_0874 gi|489771689| peroxiredoxin [Lactobacillus reuteri] 99.465 187 1 0 1 561 1 187 3.64E−140 387 ref|WP_003675595.1| TBCP-1560_g_0876 gi|512155769| LPXTG-motif cell wall anchor domain protein 99.719 356 1 0 1 1068 1 356 0 632 gb|AGN99052.1| [Lactobacillus reuteri I5007] TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 42.133 966 535 3 472 3363 139 1082 7.25E−151 502 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 42.65 966 550 2 472 3363 539 1502 6.86E−150 499 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.362 984 537 3 472 3363 49 1012 4.45E−149 496 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.667 984 534 4 472 3363 69 1032 6.36E−149 496 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.786 974 537 3 472 3363 509 1462 8.84E−149 496 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 42.17 977 525 4 472 3342 1429 2385 1.24E−148 495 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 42.402 974 527 5 472 3357 1159 2110 1.71E−148 495 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.814 959 534 3 472 3342 419 1355 2.68E−148 494 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 42.547 966 541 3 472 3363 1699 2652 4.67E−148 494 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.159 984 539 3 472 3363 349 1312 6.86E−148 493 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.615 966 540 3 472 3363 239 1182 2.26E−147 491 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.684 974 538 3 472 3363 1369 2322 1.11E−146 489 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 42.641 992 539 4 472 3357 1009 2000 1.63E−146 489 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.786 974 543 3 472 3357 259 1220 1.70E−146 489 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 42.284 972 541 3 472 3357 849 1810 1.84E−146 489 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.018 1002 525 4 472 3363 1539 2512 2.50E−146 488 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.519 1014 533 7 472 3363 1559 2562 2.75E−146 488 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 42.427 964 541 3 472 3357 1269 2220 3.72E−146 488 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 42.029 966 536 3 472 3363 829 1772 4.08E−146 488 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.273 974 532 4 472 3363 2279 3222 4.44E−146 488 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.718 966 539 3 472 3363 989 1932 7.66E−146 487 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 42.186 979 542 2 472 3342 1819 2795 1.46E−145 486 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.822 966 538 3 472 3363 719 1662 1.56E−145 486 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.383 969 534 4 472 3342 679 1625 2.27E−145 486 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.889 974 546 2 472 3363 2129 3092 3.28E−145 485 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.833 1004 534 4 472 3363 1289 2282 3.50E−145 485 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.273 974 538 3 472 3357 19 970 8.00E−145 484 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.65 982 543 3 472 3357 1209 2180 9.04E−145 484 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.925 966 537 3 472 3363 1189 2132 1.41E−144 483 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.955 982 540 4 472 3357 1769 2740 1.78E−144 483 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.159 984 549 3 472 3363 649 1622 3.52E−144 482 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 40.744 994 539 4 472 3363 2079 3052 1.29E−143 481 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.803 976 534 5 472 3363 1879 2832 1.72E−143 480 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 40.895 961 534 3 511 3357 2 940 5.58E−142 476 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.147 994 535 6 472 3363 2149 3122 7.97E−142 475 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 40.335 1014 535 8 472 3363 2169 3162 2.26E−140 471 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 42.105 969 547 4 472 3342 1969 2935 6.28E−140 469 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.922 947 520 4 472 3252 2299 3235 1.19E−139 469 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 41.287 901 489 2 781 3363 2 902 6.78E−136 457 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.209 1103 749 9 203 3397 2026 3068 2.67E−66 246 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.727 923 636 8 761 3397 1960 2858 6.35E−66 245 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.911 941 652 14 761 3397 650 1588 1.25E−65 244 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.877 913 647 10 761 3397 1090 1988 5.28E−65 242 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.663 879 631 3 761 3397 1880 2718 9.74E−65 241 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.793 891 635 7 761 3397 200 1058 3.06E−64 239 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 42.126 508 284 1 472 1965 2729 3236 5.92E−64 239 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.749 939 636 14 761 3397 770 1688 1.14E−63 238 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.663 879 623 7 761 3355 2020 2864 1.42E−63 238 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.119 1103 710 17 203 3397 1646 2648 1.96E−63 237 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.619 923 647 11 761 3397 90 998 2.71E−63 236 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.161 1101 742 15 203 3397 1196 2228 8.72E−63 235 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.106 1069 732 10 203 3397 816 1798 1.54E−62 234 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.818 1079 762 12 203 3397 1466 2498 4.48E−62 233 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.432 909 666 5 761 3397 20 928 6.24E−62 232 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 22.477 1090 757 9 212 3397 319 1348 3.68E−61 230 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 22.341 1119 749 16 203 3397 456 1508 6.58E−61 229 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 22.53 1012 686 11 494 3397 1371 2328 1.93E−60 228 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 22.955 880 634 6 884 3397 1 878 3.91E−60 226 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.616 885 606 9 761 3355 1010 1844 1.26E−59 225 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 22.533 1074 710 11 266 3397 1157 2138 1.50E−59 224 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 23.367 903 634 10 761 3397 1150 2018 3.96E−59 223 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 21.875 1024 696 10 482 3397 647 1618 2.26E−58 221 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 22.857 980 682 7 494 3397 201 1118 3.39E−58 220 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 22.574 979 658 16 761 3397 270 1248 1.01E−57 219 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 19.671 1154 813 32 3402 199 2057 3182 6.99E−52 200 ref|WP_050764451.1| TBCP-1560_g_0881 gi|915327763| hypothetical protein [Lactobacillus reuteri] 21.024 1113 807 25 3399 181 928 2008 1.24E−49 192 ref|WP_050764451.1| TBCP-1560_g_0882 gi|917061910| hypothetical protein [Lactobacillus reuteri] 60 30 12 0 19 108 9 38 1.04E−06 42.7 ref|WP_051668622.1| TBCP-1560_g_0887 gi|489771675| accessory Sec system protein Asp3 [Lactobacillus 100 295 0 0 1 885 1 295 0 602 ref|WP_003675581.1| reuteri] TBCP-1560_g_0889 gi|489771671| accessory Sec system glycosyltransferase 100 512 0 0 1 1536 1 512 0 1058 ref|WP_003675577.1| GtfA [Lactobacillus reuteri] TBCP-1560_g_0891 gi|512739028| hypothetical protein [Lactobacillus reuteri] 98.462 65 1 0 1 195 1 65 2.77E−17 67.4 ref|WP_016496748.1| TBCP-1560_g_0892 gi|1017201897| adhesin [Lactobacillus reuteri] 99.065 107 1 0 1 321 1 107 1.29E−58 180 ref|WP_063164570.1| TBCP-1560_g_0893 gi|1017201898| cell wall protein [Lactobacillus reuteri] 100 230 0 0 61 750 21 250 2.63E−141 420 ref|WP_063164571.1| TBCP-1560_g_0893 gi|1017201898| cell wall protein [Lactobacillus reuteri] 99.462 186 1 0 1174 1731 382 567 1.43E−21 97.8 ref|WP_063164571.1| TBCP-1560_g_0894 gi|512155787| IstB ATP binding domain-containing protein 99.519 208 1 0 1 624 1 208 2.11E−155 427 gb|AGN99070.1| [Lactobacillus reuteri I5007] TBCP-1560_g_0897 gi|489772852| potassium transporter [Lactobacillus reuteri] 100 609 0 0 1 1827 1 609 0 1095 ref|WP_003676754.1| TBCP-1560_g_0898 gi|489759560| 4-oxalocrotonate tautomerase [Lactobacillus 100 61 0 0 1 183 1 61 1.26E−39 123 ref|WP_003663508.1| reuteri] TBCP-1560_g_0899 gi|970365238| Glycerol kinase [Lactobacillus reuteri] 98.8 500 6 0 1 1500 1 500 0 948 emb|CUR43848.1| TBCP-1560_g_0900 gi|970364616| FIG00745619: hypothetical protein [Lactobacillus 100 167 0 0 1 501 1 167 5.64E−124 345 emb|CUR36442.1| reuteri] TBCP-1560_g_0903 gi|489772841| exopolysaccharide biosynthesis protein [Lactobacillus 98.969 291 3 0 1 873 1 291 0 592 ref|WP_003676743.1| reuteri] TBCP-1560_g_0904 gi|489772839| exopolysaccharide biosynthesis protein [Lactobacillus 98.712 233 3 0 1 699 1 233 1.06E−169 467 ref|WP_003676741.1| reuteri] TBCP-1560_g_0905 gi|970369186| Lipid carrier: UDP-N-acetylgalactosaminyltransferase 68.72 211 64 1 10 642 5 213 2.66E−108 309 emb|CUR42563.1| [Lactobacillus reuteri] TBCP-1560_g_0906 gi|659902175| glycosyl transferase [Lactobacillus reuteri] 63.947 380 137 0 4 1143 9 388 5.68E−172 484 gb|KEK16947.1| TBCP-1560_g_0907 gi|526245771| hypothetical protein [Lactobacillus reuteri] 25.714 420 266 13 10 1218 3 393 1.57E−36 137 ref|WP_020843125.1| TBCP-1560_g_0909 gi|970369097| capsular polysaccharide biosynthesis protein 30.952 294 190 8 136 999 57 343 2.99E−24 102 emb|CUR38065.1| [Lactobacillus reuteri] TBCP-1560_g_0915 gi|489772294| ATPase AAA [Lactobacillus reuteri] 100 245 0 0 1 735 1 245 0 506 ref|WP_003676198.1| TBCP-1560_g_0918 gi|1017201766| dTDP-glucose 4,6-dehydratase [Lactobacillus 99.711 346 1 0 1 1038 1 346 0 671 ref|WP_063164439.1| reuteri] TBCP-1560_g_0924 gi|1017201899| integrase [Lactobacillus reuteri] 97.778 315 7 0 10 954 66 380 0 644 ref|WP_063164572.1| TBCP-1560_g_0925 gi|953265103| Insertion sequence IS232 putative ATP-binding 99.592 245 1 0 1 735 1 245 0 503 emb|CUU12464.1| protein [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_0926 gi|1017201453| hypothetical protein [Lactobacillus reuteri] 31.311 412 192 16 31 1137 5 368 3.68E−39 144 ref|WP_063164126.1| TBCP-1560_g_0927 gi|518082660| hypothetical protein [Lactobacillus reuteri] 34.286 105 63 3 640 942 184 286 8.05E−07 51.2 ref|WP_019252868.1| TBCP-1560_g_0932 gi|970367365| hypothetical protein LRLP16767_LR3C6_01581 90.244 82 8 0 1 246 1 82 6.22E−49 155 emb|CUR39614.1| [Lactobacillus reuteri] TBCP-1560_g_0934 gi|489768400| homocysteine S-methyltransferase [Lactobacillus 97.742 310 7 0 1 930 1 310 0 594 ref|WP_003672322.1| reuteri] TBCP-1560_g_0936 gi|489763124| hypothetical protein [Lactobacillus reuteri] 98.824 85 1 0 1 255 1 85 4.19E−55 164 ref|WP_003667061.1| TBCP-1560_g_0939 gi|970363280| PemK family protein [Lactobacillus reuteri] 98.78 82 1 0 1 246 1 82 4.87E−57 169 emb|CUR37717.1| TBCP-1560_g_0940 gi|970363279| FIG00751385: hypothetical protein [Lactobacillus 98.75 80 1 0 1 240 1 80 6.00E−54 160 emb|CUR37716.1| reuteri] TBCP-1560_g_0941 gi|489772795| hypothetical protein [Lactobacillus reuteri] 98.374 615 10 0 1 1845 1 615 0 1117 ref|WP_003676697.1| TBCP-1560_g_0942 gi|1017201365| DEAD/DEAH box helicase [Lactobacillus 99.914 1161 1 0 1 3483 1 1161 0 2331 ref|WP_063164038.1| reuteri] TBCP-1560_g_0945 gi|518081247| exonuclease sbcCD subunit D [Lactobacillus 98.925 372 4 0 1 1116 1 372 0 763 ref|WP_019251455.1| reuteri] TBCP-1560_g_0952 gi|489768426| phosphoglycerate kinase [Lactobacillus reuteri] 98.561 278 4 0 1 834 1 278 0 544 ref|WP_003672348.1| TBCP-1560_g_0955 gi|657710404| hypothetical protein [Lactobacillus reuteri] 96.875 192 6 0 1 576 144 335 9.14E−134 377 ref|WP_029507401.1| TBCP-1560_g_0966 gi|518083012| hypothetical protein [Lactobacillus reuteri] 99.01 101 1 0 1 303 1 101 3.20E−69 201 ref|WP_019253220.1| TBCP-1560_g_0967 gi|489770069| hypothetical protein [Lactobacillus reuteri] 97.946 633 13 0 1 1899 1 633 0 1228 ref|WP_003673982.1| TBCP-1560_g_0973 gi|754210193| peptide ABC transporter substrate-binding 100 317 0 0 1 951 15 331 0 544 ref|WP_041821667.1| protein [Lactobacillus reuteri] TBCP-1560_g_0978 gi|970363231| FIG00742465: hypothetical protein [Lactobacillus 99.655 290 1 0 1 870 1 290 0 593 emb|CUR37781.1| reuteri] TBCP-1560_g_0981 gi|489770084| DNA-binding response regulator [Lactobacillus 100 217 0 0 1 651 1 217 7.49E−160 439 ref|WP_003673997.1| reuteri] TBCP-1560_g_0983 gi|489763785| hypothetical protein [Lactobacillus reuteri] 98.936 94 1 0 1 282 1 94 4.09E−51 154 ref|WP_003667721.1| TBCP-1560_g_0984 gi|512739103| molybdopterin-guanine dinucleotide biosynthesis 98.947 190 2 0 1 570 1 190 4.66E−143 395 ref|WP_016496821.1| protein MobA [Lactobacillus reuteri] TBCP-1560_g_0985 gi|489770088| molybdopterin-guanine dinucleotide biosynthesis 99.383 162 1 0 1 486 1 162 1.55E−120 335 ref|WP_003674001.1| protein B [Lactobacillus reuteri] TBCP-1560_g_0986 gi|512739104| molybdopterin molybdenumtransferase MoeA 100 405 0 0 1 1215 1 405 0 839 ref|WP_016496822.1| [Lactobacillus reuteri] TBCP-1560_g_0987 gi|512739105| molybdenum cofactor biosynthesis protein 100 165 0 0 1 495 1 165 1.98E−109 308 ref|WP_016496823.1| [Lactobacillus reuteri] TBCP-1560_g_0988 gi|512739106| molybdopterin biosynthesis protein MoeB 99.41 339 1 1 1 1014 1 339 0 697 ref|WP_016496824.1| [Lactobacillus reuteri] TBCP-1560_g_0989 gi|489770095| nitrate reductase subunit alpha [Lactobacillus 99.918 1221 1 0 1 3663 1 1221 0 2561 ref|WP_003674008.1| reuteri] TBCP-1560_g_0990 gi|489770097| nitrate reductase subunit beta [Lactobacillus 99.615 519 2 0 1 1557 1 519 0 1087 ref|WP_003674010.1| reuteri] TBCP-1560_g_0991 gi|489759699| nitrate reductase molybdenum cofactor assembly 99.479 192 1 0 1 576 1 192 6.83E−138 382 ref|WP_003663647.1| chaperone [Lactobacillus reuteri] TBCP-1560_g_0992 gi|489763803| nitrate reductase subunit gamma [Lactobacillus 100 213 0 0 1 639 1 213 2.57E−157 434 ref|WP_003667738.1| reuteri] TBCP-1560_g_0998 gi|948614637| hypothetical protein FC53_GL001335 [Lactobacillus 98.246 57 1 0 1 171 1 57 1.67E−38 120 gb|KRK46737.1| reuteri DSM 20016] TBCP-1560_g_1000 gi|489763814| beta-hydroxyacyl-ACP dehydratase [Lactobacillus 100 145 0 0 1 435 4 148 2.35E−106 298 ref|WP_003667749.1| reuteri] TBCP-1560_g_1002 gi|489770110| 3-oxoacyl-ACP synthase III [Lactobacillus 99.383 324 2 0 1 972 1 324 0 660 ref|WP_003674023.1| reuteri] TBCP-1560_g_1003 gi|148531252| phosphopantetheine-binding protein [Lactobacillus 100 82 0 0 1 246 1 82 2.24E−50 152 gb|ABQ83251.11 reuteri DSM 20016] TBCP-1560_g_1004 gi|489770114| ACP S-malonyltransferase [Lactobacillus 100 316 0 0 1 948 1 316 0 656 ref|WP_003674027.1| reuteri] TBCP-1560_g_1005 gi|489770116| beta-ketoacyl-ACP reductase [Lactobacillus 100 244 0 0 1 732 1 244 0 497 ref|WP_003674029.1| reuteri] TBCP-1560_g_1010 gi|489770124| acetyl-CoA carboxylase subunit beta [Lactobacillus 100 289 0 0 1 867 1 289 0 605 ref|WP_003674037.1| reuteri] TBCP-1560_g_1011 gi|489770126| acetyl-CoA carboxylase carboxyl transferase 100 258 0 0 1 774 1 258 6.73E−171 471 ref|WP_003674039.1| subunit alpha [Lactobacillus reuteri] TBCP-1560_g_1017 gi|868713964| putative alpha/beta hydrolase [Lactobacillus 98.089 157 3 0 1 471 129 285 2.30E−111 317 gb|AKP01217. 1| reuteri] TBCP-1560_g_1020 gi|489770141| hypothetical protein [Lactobacillus reuteri] 100 93 0 0 82 360 28 120 2.43E−45 142 ref|WP_003674054.1| TBCP-1560_g_1033 gi|489763578| two-component system response regulator 48.921 278 141 1 1 831 1 278 5.90E−99 290 ref|WP_003667514.1| [Lactobacillus reuteri] TBCP-1560_g_1034 gi|659902062| amino acid permease [Lactobacillus reuteri] 27.489 462 324 3 79 1464 23 473 1.64E−46 167 gb|KEK16839.1| TBCP-1560_g_1035 gi|148531853| Transposase and inactivated derivatives IS30 98.75 160 2 0 1 480 1 160 4.94E−117 327 gb|ABQ83852.1| family-like protein [Lactobacillus reuteri DSM 20016] TBCP-1560_g_1038 gi|970364069| Phage protein [Lactobacillus reuteri] 99.76 417 1 0 1 1251 1 417 0 833 emb|CUR37081.1| TBCP-1560_g_1042 gi|970364066| hypothetical protein LRLP16767_LRPG3B_00870 95.652 46 2 0 34 171 1 46 1.07E−26 90.1 emb|CUR37078.1| [Lactobacillus reuteri] TBCP-1560_g_1043 gi|970364065| hypothetical protein LRLP16767_LRPG3B_00869 98.857 175 2 0 1 525 1 175 7.26E−113 317 emb|CUR37077.1| [Lactobacillus reuteri] TBCP-1560_g_1044 gi|970364064| hypothetical protein LRLP16767_LRPG3B_00868 100 114 0 0 1 342 1 114 7.66E−83 236 emb|CUR37076.1| [Lactobacillus reuteri] TBCP-1560_g_1045 gi|970364063| Integrase [Lactobacillus reuteri] 99.728 367 1 0 1 1101 1 367 0 721 emb|CUR37075.1| TBCP-1560_g_1055 gi|489759851| glyoxalase [Lactobacillus reuteri] 100 130 0 0 1 390 1 130 3.04E−95 269 ref|WP_003663799.1| TBCP-1560_g_1064 gi|489770177| LysR family transcriptional regulator [Lactobacillus 100 294 0 0 1 882 1 294 0 602 ref|WP_003674090.1| reuteri] TBCP-1560_g_1066 gi|489770178| MFS transporter [Lactobacillus reuteri] 100 296 0 0 1 888 1 296 0 611 ref|WP_003674091.1| TBCP-1560_g_1067 gi|489762281| hypothetical protein [Lactobacillus reuteri] 100 34 0 0 1 102 1 34 1.28E−16 64.7 ref|WP_003666221.1| TBCP-1560_g_1076 gi|489770192| hypothetical protein [Lactobacillus reuteri] 100 560 0 0 1 1680 1 560 0 1070 ref|WP_003674105.1| TBCP-1560_g_1082 gi|489770201| ribonuclease HI [Lactobacillus reuteri] 100 131 0 0 1 393 1 131 1.34E−81 234 ref|WP_003674114.1| TBCP-1560_g_1088 gi|489770207| penicillin-binding protein 1A [Lactobacillus 100 676 0 0 1 2028 1 676 0 1342 ref|WP_003674120.1| reuteri] TBCP-1560_g_1093 gi|489770214| mevalonate kinase [Lactobacillus reuteri] 100 316 0 0 1 948 1 316 0 590 ref|WP_003674127.1| TBCP-1560_g_1094 gi|489770215| diphosphomevalonate decarboxylase [Lactobacillus 100 323 0 0 1 969 1 323 0 535 ref|WP_003674128.1| reuteri] TBCP-1560_g_1095 gi|489762243| phosphomevalonate kinase [Lactobacillus 99.733 375 1 0 1 1125 1 375 0 728 ref|WP_003666183.1| reuteri] TBCP-1560_g_1096 gi|489770216| type 2 isopentenyl-diphosphate Delta-isomerase 100 348 0 0 1 1044 1 348 0 686 ref|WP_003674129.1| [Lactobacillus reuteri] TBCP-1560_g_1099 gi|489770219| LacI family transcriptional regulator [Lactobacillus 100 339 0 0 1 1017 1 339 0 698 ref|WP_003674132.1| reuteri] TBCP-1560_g_1100 gi|489770220| fructokinase [Lactobacillus reuteri] 99.658 292 1 0 1 876 1 292 0 579 ref|WP_003674133.1| TBCP-1560_g_1108 gi|194452845| Cof-like hydrolase [Lactobacillus reuteri 100 272 0 0 1 816 1 272 0 560 gb|EDX41743.1| 100-23] TBCP-1560_g_1120 gi|489770238| iron transporter FeoA [Lactobacillus reuteri] 100 67 0 0 1 201 1 67 1.31E−47 144 ref|WP_003674151.1| TBCP-1560_g_1121 gi|489770239| ferrous iron transport protein B [Lactobacillus 100 663 0 0 1 1989 1 663 0 1322 ref|WP_003674152.1| reuteri] TBCP-1560_g_1125 gi|489770243| thioesterase [Lactobacillus reuteri] 100 124 0 0 1 372 1 124 1.99E−89 254 ref|WP_003674156.1| TBCP-1560_g_1128 gi|970365298| FIG00744546: hypothetical protein [Lactobacillus 100 962 0 0 1 2886 1 962 0 1945 emb|CUR43832.1| reuteri] TBCP-1560_g_1129 gi|970365299| Potassium voltage-gated channel subfamily 99.17 241 2 0 1 723 1 241 4.53E−154 427 emb|CUR43833.1| KQT; possible potassium channel, VIC family [Lactobacillus reuteri] TBCP-1560_g_1139 gi|659901251| XRE family transcriptional regulator [Lactobacillus 91.139 79 7 0 1 237 1 79 1.42E−47 144 gb|KEK16045.1| reuteri] TBCP-1560_g_1145 gi|970371392| hypothetical protein LRLP16767_LR202_00134 100 197 0 0 1 591 1 197 1.83E−140 404 emb|CUR40084.1| [Lactobacillus reuteri] TBCP-1560_g_1147 gi|489764038| hypothetical protein [Lactobacillus reuteri] 99.387 163 1 0 1 489 1 163 3.94E−93 266 ref|WP_003667972.1| TBCP-1560_g_1150 gi|489770273| hypothetical protein [Lactobacillus reuteri] 100 103 0 0 1 309 1 103 1.38E−46 144 ref|WP_003674186.1| TBCP-1560_g_1153 gi|970365843| Gluconate permease, Bsu4004 homolog 98.913 276 3 0 55 882 19 294 0 544 emb|CUR43297.1| [Lactobacillus reuteri] TBCP-1560_g_1154 gi|337727830| gluconate transport protein [Lactobacillus 100 139 0 0 1 417 239 377 8.32E−71 216 emb|CCC02917.1| reuteri ATCC 53608] TBCP-1560_g_1155 gi|915462619| transcriptional regulator [Lactobacillus reuteri] 100 334 0 0 1 1002 6 339 0 688 ref|WP_050802152.1| TBCP-1560_g_1159 gi|489762152| hypothetical protein [Lactobacillus reuteri] 100 63 0 0 1 189 1 63 8.23E−27 91.3 ref|WP_003666092.1| TBCP-1560_g_1170 gi|489762134| glycerol-3-phosphate acyltransferase [Lactobacillus 100 209 0 0 1 627 1 209 5.19E−149 411 ref|WP_003666074.1| reuteri] TBCP-1560_g_1180 gi|489762122| hemolysin III [Lactobacillus reuteri] 100 214 0 0 1 642 1 214 5.90E−120 338 ref|WP_003666062.1| TBCP-1560_g_1203 gi|754210243| integral membrane protein [Lactobacillus 100 81 0 0 1 243 1 81 9.49E−56 165 ref|WP_041821711.1| reuteri] TBCP-1560_g_1240 gi|337727907| conserved hypothetical protein [Lactobacillus 100 58 0 0 1 174 1 58 4.42E−37 116 emb|CCC02996.1| reuteri ATCC 53608] TBCP-1560_g_1270 gi|227070166| Acyltransferase [Lactobacillus reuteri MM2- 99.588 243 1 0 1 729 1 243 3.64E−179 490 gb|EEI08541.1| 3] TBCP-1560_g_1273 gi|489770423| repressor LexA [Lactobacillus reuteri] 100 208 0 0 1 624 1 208 4.21E−156 429 ref|WP_003674334.1| TBCP-1560_g_1277 gi|489770427| adenine phosphoribosyltransferase [Lactobacillus 100 172 0 0 1 516 1 172 8.74E−123 342 ref|WP_003674338.1| reuteri] TBCP-1560_g_1293 gi|489762895| 30S ribosomal protein S20 [Lactobacillus 100 84 0 0 1 252 1 84 2.02E−54 162 ref|WP_003666832.1| reuteri] TBCP-1560_g_1310 gi|489770468| peptide deformylase [Lactobacillus reuteri] 100 186 0 0 1 558 1 186 7.87E−139 384 ref|WP_003674379.1| TBCP-1560_g_1312 gi|489762866| hypothetical protein [Lactobacillus reuteri] 100 70 0 0 1 210 1 70 1.57E−47 144 ref|WP_003666803.1| TBCP-1560_g_1313 gi|489770470| diacylglycerol kinase [Lactobacillus reuteri] 100 315 0 0 1 945 1 315 0 654 ref|WP_003674381.1| TBCP-1560_g_1320 gi|512739239| sugar diacid utilization regulator [Lactobacillus 99.716 352 1 0 1 1056 1 352 0 673 ref|WP_016496953.1| reuteri] TBCP-1560_g_1328 gi|489770493| aspartate kinase [Lactobacillus reuteri] 100 452 0 0 1 1356 1 452 0 925 ref|WP_003674404.1| TBCP-1560_g_1381 gi|489762939| hypothetical protein [Lactobacillus reuteri] 100 163 0 0 1 489 1 163 2.48E−120 335 ref|WP_003666876.1| TBCP-1560_g_1407 gi|489772128| mechanosensitive ion channel protein [Lactobacillus 100 291 0 0 1 873 1 291 0 544 ref|WP_003676032.1| reuteri] TBCP-1560_g_1455 gi|489762694| 30S ribosomal protein S4 [Lactobacillus 100 201 0 0 1 603 1 201 2.21E−149 412 ref|WP_003666632.1| reuteri] TBCP-1560_g_1462 gi|489762674| hypothetical protein [Lactobacillus reuteri] 100 247 0 0 1 741 1 247 0 502 ref|WP_003666612.1| TBCP-1560_g_1466 gi|489772205| recombinase RarA [Lactobacillus reuteri] 100 434 0 0 1 1302 1 434 0 861 ref|WP_003676109.1| TBCP-1560_g_1467 gi|489762666| hypothetical protein [Lactobacillus reuteri] 100 86 0 0 37 294 13 98 2.71E−59 176 ref|WP_003666604.1| TBCP-1560_g_1469 gi|489772208| GntR family transcriptional regulator [Lactobacillus 99.178 365 3 0 1 1095 1 365 0 750 ref|WP_003676112.1| reuteri] TBCP-1560_g_1512 gi|489772257| glutamine amidotransferase [Lactobacillus 100 235 0 0 1 705 1 235 6.12E−174 476 ref|WP_003676161.1| reuteri] TBCP-1560_g_1513 gi|489763609| hypothetical protein [Lactobacillus reuteri] 99 100 1 0 1 300 1 100 1.60E−49 151 ref|WP_003667545.1| TBCP-1560_g_1519 gi|489762592| hypothetical protein [Lactobacillus reuteri] 87.94 199 24 0 1 597 1 199 7.48E−53 167 ref|WP_003666530.1| TBCP-1560_g_1522 gi|970363739| Protein of unknown function DUF1085 100 198 0 0 1 594 1 198 1.54E−149 412 emb|CUR37248.1| [Lactobacillus reuteri] TBCP-1560_g_1527 gi|489767250| hypothetical protein [Lactobacillus reuteri] 83.607 61 10 0 1 183 1 61 7.36E−23 81.3 ref|WP_003671176.1| TBCP-1560_g_1528 gi|1017201547| hypothetical protein [Lactobacillus reuteri] 66.816 223 56 1 1 669 1 205 1.54E−99 286 ref|WP_063164220.1| TBCP-1560_g_1529 gi|970369384| hypothetical protein LRLP16767_LR202_02008 97.802 91 2 0 1 273 1 91 7.44E−65 189 emb|CUR42281.1| [Lactobacillus reuteri] TBCP-1560_g_1530 gi|1017201549| hypothetical protein [Lactobacillus reuteri] 94.382 89 5 0 46 312 16 104 1.26E−59 177 ref|WP_063164222.1| TBCP-1560_g_1531 gi|1017201497| hypothetical protein [Lactobacillus reuteri] 98.551 69 1 0 1 207 1 69 2.53E−45 138 ref|WP_063164170.1| TBCP-1560_g_1535 gi|948612947| hypothetical protein FC53_GL001662 [Lactobacillus 98.496 133 2 0 1 399 14 146 2.76E−97 275 gb|KRK45104.1| reuteri DSM 20016] TBCP-1560_g_1537 gi|1017201557| hypothetical protein [Lactobacillus reuteri] 84.746 59 9 0 1 177 1 59 6.44E−32 103 ref|WP_063164230.1| TBCP-1560_g_1539 gi|512156405| Na+/H+ antiporter [Lactobacillus reuteri 99.359 156 1 0 1 468 1 156 1.40E−103 292 gb|AGN99688.1| I5007] TBCP-1560_g_1551 gi|970364845| Xylose-responsive transcription regulator, 100 242 0 0 13 738 67 308 1.50E−179 494 emb|CUR36302.1| ROK family [Lactobacillus reuteri] TBCP-1560_g_1574 gi|489772332| hypothetical protein [Lactobacillus reuteri] 100 140 0 0 1 420 1 140 8.00E−104 291 ref|WP_003676235.1| TBCP-1560_g_1579 gi|489763547| hypothetical protein [Lactobacillus reuteri] 99.485 194 1 0 1 582 1 194 1.62E−143 396 ref|WP_003667483.1| TBCP-1560_g_1589 gi|489762497| type I glyceraldehyde-3-phosphate dehydrogenase 100 335 0 0 1 1005 1 335 0 688 ref|WP_003666436.1| [Lactobacillus reuteri] TBCP-1560_g_1590 gi|737183747| hypothetical protein [Lactobacillus reuteri] 100 39 0 0 7 123 24 62 1.06E−22 79.7 ref|WP_035169635.1| TBCP-1560_g_1592 gi|512739358| MFS transporter [Lactobacillus reuteri] 100 451 0 0 1 1353 1 451 0 813 ref|WP_016497054.1| TBCP-1560_g_1594 gi|183224377| hypothetical protein [Lactobacillus reuteri 100 43 0 0 1 129 1 43 2.07E−24 84 dbj|BAG24894.1| JCM 1112] TBCP-1560_g_1595 gi|227071512| hypothetical protein HMPREF0535_0374 96.429 56 2 0 1 168 1 56 1.21E−33 107 gb|EEI09811.1| [Lactobacillus reuteri MM2-3] TBCP-1560_g_1611 gi|953265697| Lactate utilization protein A [Lactobacillus 100 298 0 0 1 894 1 298 0 595 emb|CUU13083.1| reuteri ATCC 53608] TBCP-1560_g_1626 gi|512739368| YigZ family protein [Lactobacillus reuteri] 100 210 0 0 1 630 1 210 5.01E−157 432 ref|WP_016497064.1| TBCP-1560_g_1637 gi|489763487| hypothetical protein [Lactobacillus reuteri] 100 59 0 0 1 177 1 59 1.11E−37 118 ref|WP_003667423.1| TBCP-1560_g_1647 gi|512739377| pyrroline-5-carboxylate reductase [Lactobacillus 100 257 0 0 1 771 1 257 0 513 ref|WP_016497072.1| reuteri] TBCP-1560_g_1666 gi|183224312| putative glutaredoxin [Lactobacillus reuteri 100 73 0 0 1 219 3 75 1.64E−51 154 dbj|BAG24829.1| JCM 1112] TBCP-1560_g_1667 gi|489772428| ribonucleoside-diphosphate reductase subunit 99.862 723 1 0 1 2169 1 723 0 1501 ref|WP_003676331.1| alpha [Lactobacillus reuteri] TBCP-1560_g_1669 gi|489772430| bifunctional acetaldehyde-CoA/alcohol dehydrogenase 100 878 0 0 1 2634 1 878 0 1787 ref|WP_003676333.1| [Lactobacillus reuteri] TBCP-1560_g_1676 gi|489772438| hypothetical protein [Lactobacillus reuteri] 98.684 76 1 0 1 228 1 76 3.34E−52 156 ref|WP_003676341.1| TBCP-1560_g_1688 gi|489762353| 50S ribosomal protein L33 [Lactobacillus 100 49 0 0 1 147 1 49 4.99E−32 103 ref|WP_003666293.1| reuteri] TBCP-1560_g_1695 gi|337729049| hypothetical protein LRATCC53608_1419 100 98 0 0 1 294 1 98 9.06E−70 202 emb|CCC04172.1| [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_1704 gi|970363458| FIG00746641: hypothetical protein [Lactobacillus 99.83 589 1 0 1 1767 1 589 0 1107 emb|CUR37571.1| reuteri] TBCP-1560_g_1719 gi|337729072| hypothetical protein LRATCC53608_1442 100 77 0 0 1 231 1 77 8.45E−52 155 emb|CCC04195.1| [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_1721 gi|512156590| NADH oxidase [Lactobacillus reuteri I5007] 100 48 0 0 1 144 1 48 6.82E−31 100 gb|AGN99873.1| TBCP-1560_g_1725 gi|1017201595| MarR family transcriptional regulator [Lactobacillus 100 122 0 0 1 366 1 122 3.54E−89 253 ref|WP_063164268.1| reuteri] TBCP-1560_g_1727 gi|489772083| 2-Cys peroxiredoxin [Lactobacillus reuteri] 100 166 0 0 1 498 1 166 7.45E−123 342 ref|WP_003675988.1| TBCP-1560_g_1732 gi|489770765| hypothetical protein [Lactobacillus reuteri] 100 107 0 0 1 321 1 107 2.08E−74 226 ref|WP_003674676.1| TBCP-1560_g_1733 gi|489770765| hypothetical protein [Lactobacillus reuteri] 100 348 0 0 1 1044 123 470 0 674 ref|WP_003674676.1| TBCP-1560_g_1736 gi|1017201597| hypothetical protein [Lactobacillus reuteri] 100 727 0 0 1 2181 22 748 0 1196 ref|WP_063164270.1| TBCP-1560_g_1738 gi|737175312| hypothetical protein [Lactobacillus reuteri] 100 62 0 0 1 186 1 62 7.72E−40 124 ref|WP_035161508.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 88.861 1185 116 9 1 3543 1 1173 0 1920 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 99.567 693 3 0 10978 13056 570 1262 0 1300 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 2326 4161 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 2944 4779 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 3562 5397 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 4180 6015 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 4798 6633 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 5416 7251 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 6034 7869 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 6652 8487 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 7270 9105 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 7888 9723 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 8506 10341 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 9124 10959 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 9742 11577 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 78.734 616 115 9 10360 12195 570 1173 0 917 ref|WP_016497108.1| TBCP-1560_g_1739 gi|512739413| mucus-binding protein [Lactobacillus reuteri] 38.164 207 112 9 12211 12795 569 771 2.66E−22 105 ref|WP_016497108.1| TBCP-1560_g_1754 gi|337728141| conserved hypothetical protein [Lactobacillus 100 212 0 0 1 636 1 212 1.63E−127 357 emb|CCC03232.1| reuteri ATCC 53608] TBCP-1560_g_1762 gi|489761688| cytochrome c554 [Lactobacillus reuteri] 100 46 0 0 1 138 1 46 4.72E−12 52.8 ref|WP_003665629.1| TBCP-1560_g_1765 gi|489761683| D-alanine--poly(phosphoribitol) ligase subunit 100 79 0 0 1 237 1 79 5.13E−53 158 ref|WP_003665624.1| 2 [Lactobacillus reuteri] TBCP-1560_g_1778 gi|512156647| phosphoenolpyruvate synthase [Lactobacillus 100 578 0 0 1 1734 1 578 0 1214 gb|AGN99930.1| reuteri I5007] TBCP-1560_g_1787 gi|512739432| lipoate--protein ligase A [Lactobacillus reuteri] 99.635 274 1 0 1 822 1 274 0 533 ref|WP_016497126.1| TBCP-1560_g_1804 gi|337728093| conserved hypothetical protein [Lactobacillus 100 41 0 0 1 123 1 41 1.57E−24 84 emb|CCC03183.1| reuteri ATCC 53608] TBCP-1560_g_1810 gi|512739440| DNA (cytosine-5-)-methyltransferase [Lactobacillus 100 319 0 0 1 957 1 319 0 658 ref|WP_016497134.1| reuteri] TBCP-1560_g_1816 gi|512739446| endonuclease III [Lactobacillus reuteri] 100 213 0 0 1 639 1 213 6.68E−162 444 ref|WP_016497140.1| TBCP-1560_g_1817 gi|512739447| FMN-binding domain protein [Lactobacillus 100 92 0 0 1 276 5 96 1.59E−64 188 ref|WP_016497141.1| reuteri] TBCP-1560_g_1822 gi|512156691| transposase [Lactobacillus reuteri I5007] 100 34 0 0 1 102 14 47 1.32E−19 71.2 gb|AGN99974.1| TBCP-1560_g_1824 gi|489767413| ABC transporter substrate-binding protein 100 283 0 0 1 849 1 283 0 572 ref|WP_003671339.1| [Lactobacillus reuteri] TBCP-1560_g_1826 gi|112944237| ABC-type metal ion transport system, permease 100 229 0 0 1 687 1 229 7.61E−106 304 gb|ABI26339.1| component [Lactobacillus reuteri] TBCP-1560_g_1827 gi|489761558| succinyl-diaminopimelate desuccinylase 99.738 381 1 0 1 1143 1 381 0 784 ref|WP_003665499.1| [Lactobacillus reuteri] TBCP-1560_g_1828 gi|970364154| hypothetical protein LRLP16767_LRPG3B_00672 100 36 0 0 1 108 4 39 1.71E−08 43.1 emb|CUR36880.1| [Lactobacillus reuteri] TBCP-1560_g_1852 gi|512739465| esterase [Lactobacillus reuteri] 100 180 0 0 1 540 1 180 2.49E−134 372 ref|WP_016497159.1| TBCP-1560_g_1854 gi|970363126| Cobalt-zinc-cadmium resistance protein 97.761 134 3 0 1 402 1 134 1.46E−96 273 emb|CUR37858.1| [Lactobacillus reuteri] TBCP-1560_g_1855 gi|512156721| cobalt-zinc-cadmium resistance protein [Lactobacillus 99.057 212 2 0 1 636 1 212 2.81E−137 382 gb|AGO00005.1| reuteri I5007] TBCP-1560_g_1860 gi|489770581| short-chain dehydrogenase [Lactobacillus 98.707 232 3 0 43 738 15 246 8.47E−171 469 ref|WP_003674492.1| reuteri] TBCP-1560_g_1864 gi|489770573| cyclic pyranopterin monophosphate synthase 100 162 0 0 1 486 1 162 4.27E−118 329 ref|WP_003674484.1| accessory protein [Lactobacillus reuteri] TBCP-1560_g_1868 gi|970370004| integrase [Lactobacillus reuteri] 100 411 0 0 1 1233 1 411 0 865 emb|CUR41367.1| TBCP-1560_g_1869 gi|489761612| hypothetical protein [Lactobacillus reuteri] 66.667 60 20 0 1 180 1 60 4.55E−26 89.4 ref|WP_003665553.1| TBCP-1560_g_1870 gi|970370006| hypothetical protein LRLP16767_LR202_01424 98.857 175 2 0 1 525 1 175 3.54E−130 361 emb|CUR41369.1| [Lactobacillus reuteri] TBCP-1560_g_1872 gi|970370008| hypothetical protein LRLP16767_LR202_01426 99.582 958 4 0 1 2874 1 958 0 1981 emb|CUR41371.1| [Lactobacillus reuteri] TBCP-1560_g_1873 gi|970370009| hypothetical protein LRLP16767_LR202_01427 100 122 0 0 1 366 1 122 1.50E−87 249 emb|CUR41372.1| [Lactobacillus reuteri] TBCP-1560_g_1876 gi|503689749| lysozyme M1 (1,4-beta-N-acetylmuramidase) 86.047 129 18 0 187 573 1 129 6.65E−81 237 ref|WP_013923825.1| [Lactobacillus reuteri] TBCP-1560_g_1877 gi|489759748| spore coat protein CotH [Lactobacillus reuteri] 26.557 305 188 9 10 888 1058 1338 1.70E−19 88.2 ref|WP_003663696.1| TBCP-1560_g_1882 gi|970369249| hypothetical protein LRLP16767_LR202_02167 94.258 209 12 0 1 627 81 289 8.41E−120 340 emb|CUR42509.1| [Lactobacillus reuteri] TBCP-1560_g_1883 gi|915462620| mobilization protein [Lactobacillus reuteri] 97.512 402 10 0 1 1206 11 412 0 738 ref|WP_050802153.1| TBCP-1560_g_1884 gi|489770545| hypothetical protein [Lactobacillus reuteri] 95.408 196 9 0 1 588 1 196 4.22E−127 355 ref|WP_003674456.1| TBCP-1560_g_1908 gi|489772006| 3,4-dihydroxy-2-butanone-4-phosphate synthase 100 220 0 0 1 660 1 220 6.96E−165 452 ref|WP_003675911.1| [Lactobacillus reuteri] TBCP-1560_g_1909 gi|970364398| Beta-phosphoglucomutase [Lactobacillus reuteri] 99.531 213 1 0 1 639 1 213 2.61E−144 400 emb|CUR36668.1| TBCP-1560_g_1944 gi|970364175| hypothetical protein LRLP16767_LRPG3B_00662 100 37 0 0 1 111 1 37 7.76E−23 79.3 emb|CUR36870.1| [Lactobacillus reuteri] TBCP-1560_g_1953 gi|512739498| branched-chain amino acid transporter [Lactobacillus 100 107 0 0 1 321 1 107 2.65E−74 214 ref|WP_016497191.1| reuteri] TBCP-1560_g_1954 gi|490698967| branched-chain amino acid transporter AzlC 100 230 0 0 1 690 1 230 5.57E−139 388 ref|WP_004562469.1| [Lactobacillus reuteri] TBCP-1560_g_1958 gi|337729002| hypothetical protein LRATCC53608_1370 97.826 46 1 0 1 138 1 46 1.12E−26 89.7 emb|CCC04122.1| [Lactobacillus reuteri ATCC 53608] TBCP-1560_g_1968 gi|512739505| RNA-binding protein [Lactobacillus reuteri] 100 255 0 0 1 765 1 255 0 521 ref|WP_016497198.1| TBCP-1560_g_1969 gi|970370437| Inner membrane protein translocase component 100 263 0 0 1 789 15 277 2.91E−158 440 emb|CUR40976.1| YidC, short form OxaI-like [Lactobacillus reuteri] TBCP-1560_g_1970 gi|489761281| ribonuclease P protein component [Lactobacillus 100 117 0 0 1 351 1 117 6.87E−84 239 ref|WP_003665224.1| reuteri]

The beneficial technical effects of the present disclosure are as follows.

The strain CCFM8631 of Lactobacillus reuteri of the present disclosure significantly increases neurotransmitter 5-hydroxytryptamine (5-HT) level in peripheral blood of rat, regulates brain-gut axis, relieves mental illnesses related to metabolic syndrome, for example anxiety, depression and so on, recovers the hormone level, for example testosterone and so on in peripheral blood of rat caused by high-fat high-starch diet, recovers abundances of Bifidobacterium genus, Turicibacter genus, Oscillospira genus and Blautia genus in abnormal intestinal flora of rat affected by high-fat high-starch diet. In addition, strain CCFM8631 of Lactobacillus reuteri has pretty good tolerance to simulated gastrointestinal fluid, and quickly colonizes in intestinal, significantly alleviates pathology damages of tissues, such as liver, duodenum and so on of rat with metabolic syndrome caused by high-fat high-starch diet; significantly improves oral glucose tolerance of rat with metabolic syndrome and decreases the under curve area of glucose tolerance test; significantly increases triglyceride and total cholesterol levels in serum of rat with metabolic syndrome caused by high-fat high-starch diet. The strain CCFM8631 of Lactobacillus reuteri of the present disclosure can be used to prepare health foods or medicines that improve metabolic syndrome, regulates intestinal flora, relieves irritable bowel syndrome, regulates brain-gut axis and alleviates mental illness such as anxiety, depression and so on, which has a pretty wide application prospect.

In order to understand the present disclosure further, the technical solutions in the examples of the present disclosure will be described clearly and completely herein in conjunction with the examples of the present disclosure. Apparently, the described examples are only a part of the examples of the present disclosure, rather than all examples. Based on the examples in the present disclosure, all of other examples, made by one of ordinary skill in the art without any creative efforts, fall into the protection scope of the present disclosure.

All of the reagents related to examples of the present disclosure are commercial products without special description, which can be purchased on market. All of the following examples are completed by theory and technology research group of probiotics of Research Center of Food Biotechnology in School of Food Science and Technology, Jiangnan University.

Example 1: Strain CCFM8631 of Lactobacillus reuteri has Good Tolerance to Simulated Gastrointestinal Fluid

The cryopreserved strain CCFM8631 of Lactobacillus reuteri were inoculated in the MRS medium and cultured at 37° C. for 48 hours under anaerobic cultivation, followed by 2 to 3 times subculture in MRS liquid medium. The medium with strain CCFM8631 of Lactobacillus reuteri was taken and centrifuged for 5 minutes at a speed of 8000 g, and then resuspended (1:1) in an artificial simulated gastric juice (MRS medium containing 1% pepsin, pH 2.5), followed by anaerobic cultivation at 37° C. Sampling was carried out at 0 hour and 3 hours, and the samples were cultured on MRS medium agar plate for colony counting. The viability numbers were counted and the survival rates were calculated. The survival rate is the rate of the viable count at the desired time point to the viable count at the 0 hour, which was expressed in %.

The medium with cultured strain CCFM8631 of Lactobacillus reuteri was taken and centrifuged at a speed of 8000×g for 5 minutes. The bacteria were collected and resuspened (1:1) in artificial simulated intestinal fluid (MRS medium containing 0.3% bile salt from ox, 1% trypsin, pH 8.0), followed by anaerobic cultivation at 37° C. Sampling was carried out at 0 hour and 4 hours, and the samples were cultured on MRS medium agar plate for colony counting. The viability numbers were counted and the survival rates were calculated. The survival rate is the rate of the viable count at the desired time point to the viable count at the 0 hour, which was expressed in %.

The experiment results were shown in Table 2. The results showed that strain CCFM8631 of Lactobacillus reuteri has a relative good tolerance to simulated gastrointestinal fluid.

TABLE 2 Tolerance of strain CCFM8631 of Lactobacillus reuteri to simulated gastrointestinal fluid Simulated Simulated Gastric Fluid Gastric Fluid Treatment Time (h) 3 4 Survival Rate (%) 88.1 ± 5.3 67.5 ± 7.2

Example 2: Strain CCFM8631 of Lactobacillus reuteri has No Toxic and Side Effects on SD Rat

The strain CCFM8631 of Lactobacillus reuteri bacteria were resuspended in 2% sucrose solution to give a bacterial suspension with a concentration of 3.0×10⁹ CFU/mL. 8 healthy male SD rats with a weight between 180 and 200 g were chosen and acclimated for 1 week before experiments. The rats were administered with the above bacteria suspension by intragastric gavage once daily at a dose of 2 mL/day/rat. The death and weight of the rats were observed and recorded for one week. The results were shown in Table 3.

TABLE 3 Death and changes of body weight in rats Time (day) 1 2 3 4 5 6 7 Weight (g) 228.2 ± 0.9 235.3 ± 1.1 241.1 ± 0.5 246.7 ± 0.7 252.0 ± 0.2 258.2 ± 1.3 264.5 ± 0.4 Death — — — — — — — Comment: “—”, no death.

The results showed that administration of strain CCFM8631 of Lactobacillus reuteri with a concentration of 3.0×10⁹ CFU/mL did not have significant influences on rats, there was no significant change on the body weight and no death. There were no obvious pathological symptoms in the appearance of the rats.

Example 3: Strain CCFM8631 of Lactobacillus reuteri has Good Recovery Effect on Tissue Damages of Liver, Duodenum and so on in Rats with Metabolic Syndrome

48 healthy male SD rats with weight from 180 to 200 g were chosen and acclimated for 1 week. The rats were divided into 6 groups randomly: non-specific control group (NC), high-fat high-starch (HFHS) diet model control group, simvastatin control group (SC), rosiglitazone hydrochloride control group (RH), strain CCFM8631 of Lactobacillus reuteri intervention group (CCFM8631), Lactobacillus rhamnosus LGG control group (LGG), 8 rats per group. The rats were administered with the bacteria suspension (3.0×10⁹ CFU/mL, in 2% sucrose solution) by intragastric gavage. Grouping and treatment method were shown in Table 4.

TABLE 4 Grouping and treatment method of the experiment Number Treatment Method: of rats/ Treatment administrated by intra- Group Group Duration Feed gastric gavage daily NC 8 12 Weeks Normal feed 2 ml of 2% sucrose solution HFHS 8 12 Weeks High-fat 2 ml of 2% sucrose high-starch solution feed SC 8 12 Weeks High-fat 2 ml of 2% sucrose high-starch solution containing 3 feed mg/kg/BW/d of simvastatin RH 8 12 Weeks High-fat 2 ml of 2% sucrose high-starch solution containing 10 feed mg/kg/BW/d of rosiglitazone hydrochloride CCFM8631 8 12 Weeks High-fat 2 ml of 2% sucrose high-starch solution containing feed 3.0 × 10⁹ CFU/mL of CCFM8631 LGG 8 12 Weeks High-fat 2 ml of 2% sucrose high-starch solution containing feed 3.0 × 10⁹ CFU/mL of LGG of

At the end of the experiment, the rats were fasted (with access to water) for 12 hours. After administering 10% chloral hydrate by peritoneal injection, the rats were anesthetized, the blood samples were collected from the hearts, and the rats were sacrificed by cervical dislocation. The blood samples were centrifuged at a speed of 3000×g at 4° C. for 10 minutes. The supernatant was collected and frozen at −80° C. for later use. Liver, duodenum and so on were collected and quickly put into ice-cold physiological saline to wash away the blood, followed by fixation in paraformaldehyde. In addition, small intestine was collected and immediately frozen in liquid nitrogen.

Intestine, duodenum and so on were taken and prepared as paraffin sections, followed by HE straining. Morphology of the tissues were observed and imaged under optical microscope for pathological evaluation. The results were shown in FIGS. 2 and 3. The HE straining was performed by the following steps.

(1) Fixation: the tissue samples were washed with physiological saline and immediately put into neutral paraformaldehyde solution (4%) for fixation, and the duration of fixation was generally within 72 hours.

(2) Washing: the tissue samples were washed with running water or immersed in water for a few hours or overnight.

(3) Dehydration: the tissue samples were dehydrated by successively immersing in ethanol solutions of 70%, 80% and 90%, each for 30 minutes, and then immersing in 95% ethanol solution once for 20 minutes, immersing in 100% ethanol solution twice, each time for 10 minutes.

(4) Transparency: the tissue samples were immersed in a mixture of ½ absolute ethanol and ½ xylene for 10 minutes, xylene I for 10 minutes, and xylene II for 10 minutes (until the samples became transparent).

(5) Waxing: the tissue samples were placed in paraffin (at 62° C.) for 2 hours.

(6) Embedding: the largest side of the sample was placed in the bottom so that the sections have the largest tissue surface.

(7) Cutting: the wax blocks were cut by a manually operating microtome into slices with a thickness of 5 μm.

(8) Floatation and adhesion of sections (slice-salvaging): a water bath was used and the water was maintained at 42° C.; sections were placed onto the water surface smoothly.

(9) Drying: slides and slide rack were put into a 55° C. drying oven for about 2 hours until the wax melted.

(10) Hydration: slides were immersed in xylene I and II for 10 minutes respectively for dewaxing, and then immersed in ethanol solutions of 100%, 95%, 90%, 80% and 70% for 5 minutes respectively, and then immersed in distilled water for 3 minutes.

(11) Primary strain: the slides were put into hematoxylin solution and strained for about 20 seconds.

(12) Washing: the slides were washed with tap water for about 15 minutes until the slices became blue. Pay attention to the water flow to avoid the sections detaching from the slide.

(13) Differentiation: the slides were put into ethanol solution with 1% hydrochloric acid for 7 seconds until the slices turned red (the color became light).

(14) Rinsing: the slides were washed with tap water for 15 to 20 minutes until the color recovered blue.

(15) Re-stain: the slides were immersed in eosin solution and immediately taken out for dehydration.

(16) Dehydration: the slides were immersed in 95% ethanol solution I, 95% ethanol solution II and 70% ethanol solution successively, followed by immersing in 80% ethanol solution for 50 seconds and absolute ethanol for 2 minutes.

(17) Transparency: the slides were immersed in ½ of absolute ethanol and ½ of xylene for 1 minute, xylene I for 2 minutes and xylene II for 2 minutes, respectively.

(18) Sealing: after the treatment of xylene, the neutral balsam was used as mounting medium, which could be diluted to appropriate consistency with xylene.

FIG. 2 showed that high-fat high-starch diet caused hepatocyte microvesicular steatosis, and a number of rats have infiltration of inflammatory cell and hyperplasia of fibrous tissue. In high-fat high-starch diet model control group (HFHS), there was significant hyperplasia of fibrous tissue in liver tissue and morphologic features of early fibrosis. In strain CCFM8631 of Lactobacillus reuteri intervention group (CCFM8631), administration of strain CCFM8631 of Lactobacillus reuteri by intragastric gavage significantly improved the lesions above, and the effects were significantly better than that of group LGG FIG. 3 showed that under optical microscope, lesions of duodenum were villi broadening, interstitial edema, increase of inflammatory cells and increase of interstitial macrophages in a few cases. In strain CCFM8631 of Lactobacillus reuteri intervention group (CCFM8631), administration of strain CCFM8631 of Lactobacillus reuteri by intragastric gavage improved the lesions above, and the effects were significantly better than that of group LGG.

Example 4: Strain CCFM8631 of Lactobacillus reuteri has Recovery Effect on Intestinal Flora Imbalance Caused by High-Fat High-Starch Diet

Grouping, molding and treatment processes using SD rats were the same as described in Example 3. Before the end of the experiment, fresh feces of the rats were taken and metagenome samples were extracted. A second-generation sequencer was used for sequencing and the microbial community structure was analyzed.

The experiment results were shown in FIG. 4. In feces of high-fat high-starch diet model control group (HFHS), relative abundances of intestinal microbes Bifidobacterium genus and Turicibacter genus significantly decreased. In strain CCFM8631 of Lactobacillus reuteri intervention group (CCFM8631), intake of strain CCFM8631 of Lactobacillus reuteri leaded to a significant recovery of the relative abundances of these two genera, while drugs and LGG did not show recovery effect on the abundances of these two genera intestinal microbes. In addition, in rat feces of the high-fat high-starch diet model control group (HFHS), the relative abundance of intestinal microbes of Oscillospira genes and Blautia genus significantly increased. While in strain CCFM8631 of Lactobacillus reuteri intervention group (CCFM8631), intake of strain CCFM8631 of Lactobacillus reuteri regulated the abundance of Blautia genus back to normal level, and the effects were better than that of the drugs and LGG.

Example 5: Strain CCFM8631 of Lactobacillus reuteri Reduced (Fasting) Blood Glucose Level of Rats with Metabolic Syndrome

Grouping, molding and treatment processes using SD rats were the same as described in Example 3.

At the end of the experiment the rats were fasted (with access to water) for 12 hours and fasting blood glucose level of the rats was tested. The results were shown in FIG. 5.

In high-fat high-starch diet model control group (HFHS), fasting blood glucose level of rats significantly increased. In strain CCFM8631 of Lactobacillus reuteri intervention group (CCFM8631), administration of strain CCFM8631 of Lactobacillus reuteri by intragastric gavage significantly decreased fasting blood glucose level of model rats, approximately to non-specific control group, and its ability to decrease fasting blood glucose level of rat is better than that of rosiglitazone hydrochloride control group (RH) and Lactobacillus rhamnosus LGG control group (LGG).

Example 6: Strain CCFM8631 of Lactobacillus reuteri Increased Glucose Tolerance of Rat with Metabolic Syndrome

Grouping, molding and treatment processes using SD rats were the same as described in Example 3. At the end of the experiment, the rats were fasted (with access to water) for 12 hours. Glucose solution (2 g/kg) was injected by intraperitoneal injection and the blood glucose level was measured at 0, 30, 60 and 120 minutes. The experiment results were shown in FIGS. 6 and 7.

As shown in FIG. 6, glucose tolerance of rats in high-fat high-starch diet model control group (HFHS) was poor. After administration of glucose by intragastric gavage, blood glucose level rose significantly and decreased slowly. As shown in FIG. 7, in strain CCFM8631 of Lactobacillus reuteri intervention group (CCFM8631), administration of strain CCFM8631 of Lactobacillus reuteri by intragastric gavage significantly decreased AUC_(glucose) area, and there was no significant difference comparing with that of rosiglitazone hydrochloride control group (RH) and non-specific control group (NC). This indicated that strain CCFM8631 of Lactobacillus reuteri significantly improves oral glucose tolerance, and the effect was better than that of Lactobacillus rhamnosus LGG These results were consistent with that of the blood glucose indexes, indicating that strain CCFM8631 of Lactobacillus reuteri further decreased blood glucose level by increasing glucose tolerance.

Example 7: Strain CCFM8631 of Lactobacillus reuteri Decreased Total Cholesterol (TC) Level in Serum of Rat with Metabolic Syndrome

Grouping, molding and treatment processes using SD rats were the same as described in Example 3. At the end of the experiment, the rats were fasted (with access to water) for 12 hours. After administering 10% chloral hydrate by peritoneal injection for anesthetizing, blood sample was collected from the heart, and the rats were sacrificed by cervical dislocation. The blood samples were centrifuged at a speed of 3000×g at 4° C. for 10 minutes, and the supernatant was collected. The total cholesterol (TC) in the blood was measured according to the protocol of the detection kit. The experiment results were shown in FIG. 8.

As shown in FIG. 8, total cholesterol in serum of rats in high-fat high-starch diet model control group (HFHS) significantly increased. In strain CCFM8631 of Lactobacillus reuteri intervention group (CCFM8631), administration of strain CCFM8631 of Lactobacillus reuteri by intragastric gavage decreased level of total cholesterol in serum.

Example 8: Strain CCFM8631 of Lactobacillus reuteri Decreased Triglyceride (TG) Level in Serum of Metabolic Syndrome Rat

Grouping, molding and treatment processes using SD rats were the same as described in Example 3. At the end of the experiment, the rats were fasted (with access to water) for 12 hours. After administering 10% chloral hydrate by peritoneal injection for anesthetizing, blood sample was collected from the heart, and the rats were sacrificed by cervical dislocation. The blood samples were centrifuged at a speed of 3000×g at 4° C. for 10 minutes, and the supernatant was collected. The triglyceride (TG) level in the blood was measured according to the protocol of the detection kit. The experiment results were shown in FIG. 9.

As shown in the experiment results, comparing with non-specific control group (NC), triglyceride level in serum of rats in high-fat high-starch diet model control group significantly increased. In strain CCFM8631 of Lactobacillus reuteri intervention group, administration of strain CCFM8631 of Lactobacillus reuteri by intragastric gavage decreased triglyceride level in serum, and the effect was better than that of LGG

Example 9: Strain CCFM8631 of Lactobacillus reuteri Affected 5-HT and Testosterone Levels in Serum of Rat with Metabolic Syndrome

Grouping, molding and treatment processes using SD rats were the same as described in Example 3. At the end of the experiment, the rats were fasted (with access to water) for 12 hours. After administering 10% chloral hydrate by peritoneal injection for anesthetizing, blood sample was collected from the heart, and the rats were sacrificed by cervical dislocation. The blood samples were centrifuged at a speed of 3000×g at 4° C. for 10 minutes, and the supernatant was collected. The 5-HT and testosterone levels in the blood were measured according to the protocol of the detection kit.

The experiment results were shown in FIG. 10. As shown in the experiment results, strain CCFM8631 of Lactobacillus reuteri significantly increased 5-HT level in serum of rats, while LGG has no significant improvement on 5-HT level. Comparing with non-specific control group (NC), testosterone level in serum of rats in high-fat high-starch diet model control group (HFHS) significantly increased. In strain CCFM8631 of Lactobacillus reuteri intervention group (CCFM8631), administration of strain CCFM8631 of Lactobacillus reuteri by intragastric gavage reduced the testosterone level in serum back to normal, and LGG can decrease the testosterone level greatly lower than normal level in model rats. 

What is claimed is:
 1. A method of improving metabolic syndrome, modulating intestinal flora, improving irritable bowel syndrome, modulating brain-gut axis, relieving anxiety and/or depression, comprising administering a strain CCFM8631 of Lactobacillus reuteri which is deposited at China General Microbiological Culture Collection Center (CGMCC) with an accession number CGMCC 14394, to a subject in need thereof.
 2. The method according to claim 1, wherein the improving of metabolic syndrome is to relieve the symptoms of hyperglycemia and hyperlipidemia, inflammation of liver and duodenum, and liver fibrosis; the modulating of intestinal flora is to normalize abnormal abundances of Blautia genus, Turicibacter genus, Oscillospira genus and Bifidobacterium genus in the intestinal flora; and the modulating of brain-gut axis and the relieving of anxiety and/or depression is to increase 5-hydroxytryptamine level in peripheral blood.
 3. A method for preparing a composition, comprising: inoculating the strain CCFM8631 of Lactobacillus reuteri to MRS medium at an inoculum size of 2 to 4 wt %, culturing for 18 to 20 h at 37° C. under anaerobic condition, collecting bacteria, resuspending the bacteria with a protectant to a bacterial density of 10¹⁰ CFU/mL, culturing the suspension at 37° C. for 50 to 70 minutes under anaerobic condition, and drying the resulting culture, wherein the strain CCFM8631 is deposited at China General Microbiological Culture Collection Center (CGMCC) with an accession number CGMCC
 14394. 4. The method according to claim 3, wherein the protectant is a aqueous solution containing 100 g/L to 150 g/L of nonfat milk powder, 100 g/L to 150 g/L of maltodextrin, and 140 g/L to 160 g/L of trehalose; the drying is vacuum freeze-drying after pre-freezing at −15 to −20° C. for 8 to 14 h. 